Mutant staphylococcus beta-glucuronidase enzymes with enhanced enzymatic activity

ABSTRACT

Mutated  Staphylococcus  sp. RLH1 β-glucuronidase enzymes with enhanced enzymatic activity and thermostability as compared to wild type enzyme are provided. The enzymes of the invention advantageously allow for accurate analysis of bodily samples for the presence of drugs in 30 minutes or less, as compared to the several hours needed using prior enzyme preparations. Methods of using the mutated enzymes for hydrolysis of glucuronide substrates, including opiates and benzodiazepines, are also provided.

RELATED APPLICATIONS

This application is a continuation-in-part of U.S. application Ser. No. 14/867,710, filed on Sep. 28, 2015, which claims the benefit of the priority date of U.S. Provisional Application No. 62/056,800, filed on Sep. 29, 2014. The contents of these applications are hereby incorporated by reference in their entireties.

BACKGROUND OF THE INVENTION

In mammals, glucuronidation is one of the principle means of detoxifying or inactivating compounds using the UDP glucuronyl transferase system. Compounds are conjugated by the glucoronyl transferase system to form glucuronides, which are then secreted in urine or into the lower intestine in bile. Furthermore, microorganisms in the gut, such as Escherichia coli, have evolved to utilize the excreted β-glucuronides as a carbon source. The β-glucuronidase (BGUS) enzyme catalyzes the hydrolysis of a wide variety of β-glucuronides. Thus, BGUS enzyme activity been reported in those organisms that utilize glucuronidation as a detoxification pathway, as well as in some of their endogenous microbe populations. All vertebrates and many mollusks, as well as certain bacteria, exhibit BGUS enzyme activity, whereas insects and plants that utilize a different detoxification pathway typically do not exhibit BGUS enzyme activity.

Given the key role of glucuronidation in detoxification of compounds, the BGUS enzyme has been used for detection of drugs in bodily samples, such as to detect the presence of illicit drugs in bodily samples of criminal suspects. For example, a bodily sample can be tested for the presence of a suspected drug by detecting the hydrolysis of the glucuronide form of the drug by BGUS.

Commercially available preparations of BGUS enzyme, for use for example in drug testing, include crude extract forms of the E. coli, snail and abalone versions of the enzyme. While these preparations are effective in hydrolyzing glucuronides, they typically include other proteins in addition to the BGUS, which may interfere with enzyme activity. Moreover, importantly, their level of enzyme activity is such that they typically require at least several hours (e.g., three hours or more) to analyze a sample. Including sample preparation time and analysis time, this means that evaluation of a drug sample typically can take at least two days using currently commercially available BGUS preparations.

Accordingly, there is a need for BGUS enzymes with enhanced activity that are more efficient for use in drug testing.

SUMMARY OF THE INVENTION

The invention provides mutant forms of BGUS enzymes that exhibit enhanced enzymatic activity as compared to wild type enzyme. Moreover, mutant forms of BGUS described herein exhibit higher thermal stability than the wild type enzyme. The enzymes of the invention advantageously allow for accurate analysis of bodily samples for the presence of drugs in 30 minutes or less, as compared to the several hours needed using the current commercially available enzyme preparations, thereby allowing for completion of analyses within a shorter time frame than previously possible. Furthermore, the mutant enzymes of the invention are produced recombinantly and thus can be prepared in a highly purified form without contaminating non-BGUS proteins and with a higher temperature stability.

In one aspect, the invention pertains to a mutated Staphylococcus sp. RLH1 β-glucuronidase (StBGUS) enzyme comprising a substitution of an amino acid corresponding to G563 in SEQ ID NO: 42 with an amino acid comprising a side chain comprising a non-aromatic hydroxyl group or histidine or asparagine. In one embodiment of the mutated StBGUS enzyme, the amino acid corresponding to G563 in SEQ ID NO: 42 is substituted with a serine or threonine. In another embodiment, the amino acid corresponding to G563 in SEQ ID NO: 42 is substituted with a serine. In one embodiment, the mutated StBGUS enzyme has the amino acid sequence shown in SEQ ID NO: 98. In one embodiment, the mutated StBGUS enzyme is encoded by the nucleotide sequence shown in SEQ ID NO: 97.

In another aspect, the invention pertains to a mutated Staphylococcus sp. RLH1 β-glucuronidase (StBGUS) enzyme comprising an addition of a cysteine residue appended at or near the carboxy terminus of the enzyme, wherein the carboxy terminus has the sequence: Xaa_(0.8)-Cys-Xaa₀₋₂, wherein Xaa=any amino acid (SEQ ID NO: 99). In one embodiment, the mutated StBGUS having a cysteine appended at or near the carboxy terminus has the amino acid sequence shown in SEQ ID NO: 100.

In yet another aspect, the invention pertains to a mutated Staphylococcus sp. RLH1 β-glucuronidase (StBGUS) enzyme comprising:

-   -   (i) a substitution of an amino acid corresponding to G563 in SEQ         ID NO: 42 with an amino acid comprising a side chain comprising         a non-aromatic hydroxyl group or histidine or asparagine; and     -   (ii) an addition of a cysteine residue appended at or near the         carboxy terminus of the enzyme, wherein the carboxy terminus has         the sequence: Xaa_(0.8)-Cys-Xaa₀₋₂, wherein Xaa=any amino acid         (SEQ ID NO: 99).         In one embodiment of the mutated StBGUS enzyme, the amino acid         corresponding to G563 in SEQ ID NO: 42 is substituted with a         serine or threonine. In another embodiment, the amino acid         corresponding to G563 in SEQ ID NO: 42 is substituted with a         serine. In one embodiment, the mutated StBGUS enzyme has the         amino acid sequence shown in SEQ ID NO: 101.

In another aspect, the invention provides a packaged formulation comprising a container comprising a preparation of any of the mutated StBGUS enzymes disclosed herein, wherein the preparation has an enzymatic activity of at least 5,000 Units/ml or 5,000 Units/mg. In one embodiment, the preparation is an aqueous solution with an enzymatic activity of at least 50,000 Units/ml. In another embodiment, the preparation is a lyophilized preparation with an enzymatic activity of at least 50,000 Units/mg. In one embodiment, the preparation is stable at least six months at 2-8° C. In one embodiment, the preparation lacks detectable sulfatase activity.

In yet another aspect, the invention provides a method of hydrolyzing a substrate comprising a glucuronide linkage, the method comprising contacting the substrate with any of the mutated StBGUS enzymes disclosed herein under conditions such that hydrolysis of the glucuronide linkage occurs. In one embodiment, the substrate is an opiate glucuronide. In various embodiments, the opiate glucuronide is selected from the group consisting of morphine-3β-D-glucuronide, morphine-6β-D-glucuronide, codeine-6β-D-glucuronide, hydromorphone-3β-D-glucuronide, oxymorphone-3β-D-glucuronide, and combinations thereof. In another embodiment, the substrate is a benzodiazepine glucuronide. In various embodiments, the benzodiazepine glucuronide is selected from the group consisting of oxazepam-glucuronide, lorazepam-glucuronide, temazepam-glucuronide, alprazolam, alpha-hydroxy-alprazolam glucuronide, nordiazepam, 7-amino-clonozepam, and combinations thereof. In various embodiments, the substrate is in a sample of blood, urine, tissue or meconium obtained from a subject.

Other features and aspects of the invention are described in further detail herein.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an alignment of the amino acid sequences of the K1S (SEQ ID NO: 19), K1T (SEQ ID NO: 20), K3 (SEQ ID NO: 21), K3Δ1 (SEQ ID NO: 22), K3Δ2 (SEQ ID NO: 23) and K3Δ2S (SEQ ID NO: 24) mutants as compared to the wild type E. coli K12 sequence (SEQ ID NO: 18). The F385 through S396 modification region, G559S or G559T modifications and C-terminal GLC modification in the mutants are highlighted in bold and underlined.

FIG. 2 is an alignment of the amino acid sequences of the E. coli K3 mutant (K3) (SEQ ID NO: 25), the abalone (Ab) wild type BGUS (SEQ ID NO: 26), the human (Hu) wild type BGUS (SEQ ID NO: 27), the Lactobacillus brevis (L. br.) wild type BGUS (SEQ ID NO: 28) and the Staphylococcus sp. RLH1 (S. rlh) wild type BGUS (SEQ ID NO: 29) across amino acid residues 332-416 (E. coli numbering), including across the modification region F385 through S396 (E. coli numbering). Identical amino acid residues across the five sequences are highlighted in grey. The conserved glutamic acid residue (E) at position 413 (E. coli numbering) within the catalytic site is highlighted in bold, indicating the accuracy of the alignment. The modification region F385 through S396 (E. coli numbering) is highlighted in bold and underlined.

FIG. 3 is an alignment of the amino acid sequences of the E. coli K3 mutant (K3) (SEQ ID NO:30), the abalone (Ab) wild type BGUS (SEQ ID NO:31), the human (Hu) wild type BGUS (SEQ ID NO:32), the Lactobacillus brevis (L. br.) wild type BGUS (SEQ ID NO: 33) and the Staphylococcus sp. RLH1 (S. rlh) wild type BGUS (SEQ ID NO: 34) across amino acid residues 452-606 (E. coli numbering), including across the G559S modification (E. coli numbering) and the C-terminal GLC modification. Identical amino acid residues across the three sequences are highlighted in grey. The conserved tyrosine residue (Y) at position 468 and the conserved glutamic acid residue (E) at position 504 (E. coli numbering) within the catalytic site are highlighted in bold, indicating the accuracy of the alignment. The G559S mutation position (E. coli numbering) and C-terminal GLC modifications are highlighted in bold and underlined.

FIG. 4 is a bar graph showing the specific enzyme activity (in MU/g of protein) of the K1S mutant, as compared to the wild type E. coli 12 BGUS enzyme, using phenolphthalein-glucuronide as the substrate. Both samples are purified and normalized to protein concentration.

FIG. 5 is a bar graph showing the specific enzyme activity (as measured by OD at 405 nm) of the K1S mutant, as compared to the wild type E. coli 12 BGUS enzyme and a thermo-resistant mutant (TR), using 4-nitrophenol glucuronide as the substrate. All three samples are purified and normalized to protein concentration.

FIG. 6 is a bar graph showing the specific enzyme activity (in MU/g of protein) of the K1T, K3, K3-C606S and K3Δ1 mutants, as compared to the K1S mutant, using phenolphthalein-glucuronide as the substrate. The results were normalized to total protein concentration.

FIG. 7A is a graph showing enzyme activity across various pH levels for the BGUS mutant K3.

FIG. 7B is a graph showing enzyme activity after overnight storage at different pH levels, following by return of the pH to neutral levels and testing of enzymatic activity for the BGUS mutant K3.

FIG. 8 is a photograph of an SDS-PAGE gel showing the purity of the recombinant K3 enzyme (lane 2) as compared to commercially available abalone (lane 3), snail (lane 4) and E. coli (lane 5) extracts. Molecular weight markers are shown in lane 1.

FIG. 9A is an alignment of the wild type abalone BGUS (Wt-Ab) amino acid sequence (SEQ ID NO: 26) with representative loop region insertion mutants Ab1 (SEQ ID NO: 35) and Ab2 (SEQ ID NO: 36) across the loop region F385 through Y395 (E. coli numbering).

FIG. 9B is an alignment of the wild type human BGUS (Wt-Ab) amino acid sequence (SEQ ID NO: 27) with representative loop region insertion mutants Hu1 (SEQ ID NO: 37) and Hu2 (SEQ ID NO: 38) across the loop region F385 through Y395 (E. coli numbering).

FIG. 10 is a graph showing enzyme activity at four different temperatures for the BGUS mutant K3.

FIG. 11 is a graph showing enzyme activity for BGUS mutants having the indicated amino acid substitution at position 559, demonstrating enhanced enzyme activity for substitutions with histidine (H), asparagine (N), serine (S) and threonine (T).

FIG. 12 is a graph showing enzyme activity for BGUS mutants having insertions or substitutions near the carboxy terminus, demonstrating that such mutations do not affect the overall enzyme activity or the thermostability. Purified enzymes were heat treated for one hour prior to measuring their enzymatic activity.

FIG. 13 is a graph showing enzyme activity for Staphylococcus sp. RLH1 β-glucuronidase mutant having a G563S substitution (St1F), demonstrating enhanced enzyme activity for the mutant as compared to wild type enzyme (StBGUS).

DETAILED DESCRIPTION OF THE INVENTION

The invention pertains to mutated β-glucuronidase enzymes having enhanced enzymatic activity as compared to the wild type enzyme, as well as packaged formulations thereof and methods of using the enzymes for hydrolysis of glucuronide linkages. Various aspects of the invention are described in further detail in the following subsections.

I. Mutated β-Glucuronidase Enzymes

A. Position 559 Substitutions

As used herein, the term “β-glucuronidase enzyme”, also referred to as “β-glucuronidase” or “BGUS”, refers to an enzyme that hydrolyzes β-glucuronide linkages. A “wild type” BGUS enzyme refers to the naturally occurring form of the enzyme. A “mutated” BGUS enzyme refers to a modified form of the enzyme in which one or more modifications, such as amino acid substitutions, deletions and/or insertions, have been made such that the amino acid sequence of the mutated BGUS enzyme differs from the wild type amino acid sequence. The nucleotide sequence encoding wild type E. coli K12 strain BGUS is shown in SEQ ID NO: 1 (NCBI Reference Sequence: NC_000913.2). The amino acid sequence of wild type E. coli K12 strain BGUS is shown in SEQ ID NO: 18 and in FIG. 1. Cloning of the wild type E. coli K12 strain BGUS is described in detail in Example 1.

It has now been discovered that a single amino acid substitution of an amino acid corresponding to G559 in SEQ ID NO: 18 (wild type E. coli BGUS) with an amino acid comprising a side chain comprising a non-aromatic hydroxyl group, or with histidine or asparagine, creates a mutated BGUS enzyme that has significantly enhanced (e.g., at least 3-fold greater) enzymatic activity as compared to the wild type enzyme. As used herein, a “side chain” of an amino acid refers to the “R” group in the standard generic formula for amino acids: H₂NCHRCOOH. A “non-aromatic hydroxyl group” refers to a side chain structure that contains an —OH group, but that lacks a ring structure. In one embodiment, the amino acid comprising a side chain comprising a non-aromatic hydroxyl group is serine (i.e., the mutation in the enzyme consists of a G559S substitution). In another embodiment, the amino acid comprising a side chain comprising a non-aromatic hydroxyl group is threonine (i.e., the mutation in the enzyme consists of a G559T substitution). In yet other embodiments, the amino acid comprising a side chain comprising a non-aromatic hydroxyl group can be a non-naturally occurring amino acid. Non-limiting examples of non-natural amino acids comprising a side chain comprising a non-aromatic hydroxyl group include L-iso-serine (Sigma Aldrich Product #06054), L-allo-threonine (Sigma Aldrich Product #210269), homoserine (Swiss Side Chain ID#HSER), 3-3-dihydoxyalanine (Swiss Side Chain ID#DDZ) and 2-amino-5-hydroxypentanoic acid (Swiss Side Chain ID#AA4).

The preparation of mutant BGUS enzymes having either a single G559S substitution (referred to herein as K1S) or a single G559T substitution (referred to herein as K1T) is described in detail in Example 2. The full-length amino acid sequence of the K1S mutant is shown in SEQ ID: 19. The full-length amino acid sequence of the K1T mutant is shown in SEQ ID NO: 20. The alignments of the K1S and K1T mutant amino acid sequences as compared to wild-type (SEQ ID NO: 18) are shown in FIG. 1.

The enzymatic activity of the K1S enzyme as compared to wild type is described in detail in Example 4 (first experiment) and shown in FIGS. 4 and 5. This data demonstrates that the single G559S mutation imparts at least a 3-fold, or greater, enhancement in enzymatic activity of the mutant as compared to the wild type enzyme. The enzymatic activity of the K1T enzyme as compared to the K1S is described in detail in Example 4 (third experiment) and shown in FIG. 6. This data demonstrates that the single G559T mutation has a comparable, or even slightly greater enzymatic activity, than the single G559S mutation.

Xiong, A-S. et al. (2007) Prot. Eng. Design Select. 20:319-325 has reported the preparation of a mutated BGUS enzyme containing six amino acid substitutions: Q493R, T509A, M532T, N550S, G559S and N566S. This mutant enzyme is reported to have improved thermostability as compared to the wild type enzyme. However, the significantly improved enzymatic activity of the single amino acid substitution, G559S, as reported herein, is not disclosed in or suggested by Xiong et al. A comparison of the enzymatic activity of the K1S mutant (consisting of the G559S substitution) to the thermoresistant six amino acid mutant of Xiong et al. (referred to herein as “TR” and in Xiong et al. as GUS-TR3337) is described in detail in Example 4 (second experiment) and shown in FIG. 5. This data demonstrates that the K1S mutant has significantly enhanced (e.g., 3-fold greater, or more) enzymatic activity as compared to the prior art “TR” mutant enzyme.

Experiments described in Example 7 further demonstrate that substitution of the wild-type G559 position with either histidine (H) or asparagine (N) also leads to enhanced enzymatic activity. The full-length amino acid sequence of a G559H point mutant is shown in SEQ ID: 61. Accordingly, in another aspect, the invention provides a mutated β-glucuronidase enzyme comprising a substitution of an amino acid corresponding to G559 in SEQ ID NO: 18 with histidine. The full-length amino acid sequence of a G559N point mutant is shown in SEQ ID NO: 64. Accordingly, in another aspect, the invention provides a mutated β-glucuronidase enzyme comprising a substitution of an amino acid corresponding to G559 in SEQ ID NO: 18 with asparagine.

The term “substitution of an amino acid corresponding to G559 in SEQ ID NO: 18”, as used herein, references the numbering of the wild type E. coli strain 12 BGUS enzyme as shown in SEQ ID NO: 18. That is, the wild type sequence shown in SEQ ID NO: 18 has a glycine (G) at position 559 and this amino acid residue, or an amino acid residue corresponding to this residue in another BGUS sequence, is the one that is substituted.

The sequences of BGUS enzymes from numerous species are known in the art. For example, the amino acid sequence of wild type human (Homo sapiens) BGUS (isoform 1 precursor) is shown in SEQ ID NO: 39 (NCBI Reference Sequence NP_000172.2). The amino acid sequence of wild type mouse (Mus musculus) BGUS (precursor) is shown in SEQ ID NO: 40 (NCBI Reference Sequence NP_034498.1). The amino acid sequence of wild type Lactobacillus brevis BGUS is shown in SEQ ID NO: 41 (Genbank Accession No. ACU21612.1). The amino acid sequence of wild type Staphylococcus sp. RLH1 BGUS is shown in SEQ ID NO: 42 (Genbank Accession No. AAK29422.1). Furthermore, the sequences of a number of microbial BGUS enzymes are disclosed in U.S. Pat. No. 6,391,547 and EP Patent EP 1175495B, the entire contents of which, including the sequence listing, are incorporated herein by reference.

To identify “an amino acid corresponding to G559 in SEQ ID NO: 18” in a BGUS enzyme sequence other than E. coli K12 strain, one of skill in the art can align the BGUS enzyme sequence to SEQ ID NO: 18 using standard computer programs for identifying protein homologies to determine the “best fit” alignment to thereby identify an amino acid residue in the non-E. coli K12 sequence that corresponds to G559 in SEQ ID NO: 18. For example, FIG. 3 shows a representative alignment of the E. coli K12 (K3 mutant), human, abalone, Lactobacillus brevis and Staphylococcus sp. RLH1 sequences across the region spanning G559 in SEQ ID NO: 18, with the amino acid position corresponding to G559 in the five sequences indicated. Using such an approach, one of skill in the art can easily make a single amino acid substitution at the position corresponding to G559 in BGUS sequences other than E. coli K12.

Accordingly, in one embodiment of the invention, the mutated BGUS enzyme that comprises a mutation consisting of a substitution of an amino acid corresponding to G559 in SEQ ID NO: 18 is from a bacteria, preferably E. coli, more preferably E. coli strain K12. In another embodiment, the mutated BGUS enzyme is from a mollusk, such as a snail (preferably Helix pomatia) or abalone (preferably Haliotus rufenscens). In still another embodiment, the mutated BGUS enzyme is from a mammal, preferably a human.

In yet another embodiment, the mutated BGUS enzyme is a Staphylococcus sp. RLH1 enzyme (StBGUS), the wild type amino acid sequence of which is shown in SEQ ID NO: 42. The amino acid residue in SEQ ID NO: 42 that corresponds to position G559 in the E. coli sequence of SEQ ID NO: 18 is residue G563 (which is readily determined by aligning the sequences). Example 9 described the mutation of StBGUS residue G563 to serine (G563S) (referred to herein as the St1F mutant), as well as the enhanced enzymatic activity of this mutant. The amino acid sequence of the St1F mutant is shown in SEQ ID NO: 98, and the corresponding nucleotide sequence encoding the St1F mutant is shown in SEQ ID NO: 97.

B. Carboxy Terminal Cysteine Residue

It has now been discovered that appending a cysteine residue at or near the carboxy terminal end of the BGUS enzyme enhances the thermostability of the enzyme. Accordingly, in another aspect, the invention provides a mutant BGUS enzyme comprising an addition of a cysteine residue appended at or near the carboxy terminus of the enzyme. As used herein, “the carboxy terminus” (used interchangeably with “C-terminus”, “carboxy terminal end” or “C-terminal end”) of the BGUS enzyme refers to the end of the protein that terminates in a carboxyl group, according to the standard nomenclature for proteins well established in the art. As used herein, “near the C-terminal end” refers to within a few (i.e., 2-4) amino acids of the C-terminal end.

The cysteine appended to the C-terminus can be contained within a larger peptide. In a preferred embodiment, the cysteine appended to the C-terminus is contained within the following sequence: Xaa₂₋₈-Cys-Xaa₀₋₂, wherein Xaa=any amino acid (SEQ ID NO: 95). For example, in a preferred embodiment, the cysteine appended to the C-terminal end is part of a tripeptide. A preferred tripeptide for addition onto the C-terminal end has the sequence Gly-Leu-Cys (GLC). Similar tripeptides with conservative substitutions as compared to the GLC tripeptide also can be used. Alternatively, the cysteine appended to the C-terminal end can be part of, for example, a pentapeptide. A preferred pentapeptide for addition to the C-terminal end has the sequence Gly-Leu-Cys-Gly-Arg (GLCGR) (SEQ ID NO: 96). Other exemplary mutant BGUS enzymes having a cysteine appended at or near (within 2 residues of) the C-terminal end have the amino acid sequences shown in SEQ ID NOs: 21, 62, 63, 65, 66-78, 93 and 94.

The preparation of mutant BGUS enzymes having a cysteine appended at the C-terminus, in the form of the tripeptide GLC is described in detail in Example 2. A representative example is a mutant referred to herein as K3, which contains the G559S mutation that is present in the K1S mutant and also contains the GLC tripeptide at its C-terminus. The full-length amino acid sequence of the K3 mutant is shown in SEQ ID NO: 21. The alignment of the K3 mutant amino acid sequence as compared to wild-type (SEQ ID NO: 18) is shown in FIG. 1.

The enzymatic activity of the K3 mutant as compared to the K1S mutant (which differ only in the addition of GLC at the C-terminus of K3) is described in detail in Example 4 (third experiment) and shown in FIG. 6. This data demonstrates that the K3 enzyme has enzymatic activity that is equal to or even slightly greater than the K1S mutant, which itself has at least 3-fold greater activity than wild type. Furthermore, the thermostability of the K3 mutant as compared to the K1S and K1T enzymes is described in detail in Examples 5 and 8 and shown in Table 3. This data demonstrates that appending the cysteine at the C-terminal end of the BGUS enzyme enhances its thermostability.

Further experiments described in Example 8 demonstrate that mutations near the cysteine at or near the carboxy terminus do not affect the overall enzyme activity or thermal stability; rather, that it is only the cysteine residue that is critical for enhanced thermal stability of the enzyme. Various mutant enzymes were made having the cysteine appended to the C-terminus contained within the following sequence: Xaa₂₋₈-Cys-Xaa₀₋₂, wherein Xaa=any amino acid (SEQ ID NO: 95). A representative full length amino acid sequence is shown in SEQ ID NO: 93. The results of the analysis showed that the various mutations and insertions around the appended cysteine residue did not affect the enzymatic activity or thermal stability. Thus, it is possible to insert amino acids upstream or downstream of the cysteine residue or make amino acid substitutions at positions adjacent to the cysteine residue without affecting overall enzyme activity or thermal stability.

As discussed above, the sequences of BGUS enzymes from numerous species are known in the art. Accordingly, a cysteine residue (preferably in the form of a GLC tripeptide or a GLCGR pentapeptide) can be appended to the C-terminus of BGUS sequences from E. coli as well as from other species. For example, FIG. 3 shows a representative alignment of the E. coli K12 (K3 mutant), human, abalone, Lactobacillus brevis and Staphylococcus sp. RLH1 sequences with the C-terminal appended cysteine in the K3 mutant indicated. Thus, in one embodiment of the invention, the mutated BGUS enzyme that comprises a cysteine appended to the C-terminus is from a bacteria, preferably E. coli, more preferably E. coli strain K12. In another embodiment, the mutated BGUS enzyme is from a mollusk, such as a snail (preferably Helix pomatia) or abalone (preferably Haliotus rufenscens). In still another embodiment, the mutated BGUS enzyme is from a mammal, preferably a human.

In yet another embodiment, the mutated BGUS enzyme with a cysteine appended to the C-terminus is from Staphylococcus sp. RLH1 (StBGUS). The amino acid sequence of a representative StBGUS C-terminal cysteine mutant (having a single cysteine residue appended at the C-terminus) is shown in SEQ ID NO: 100. In alternative embodiments, a mutated StBGUS enzyme having a cysteine appended at or near the C-terminus can comprise the wild-type sequence (SEQ ID NO: 42) with the following sequence: Xaa₀₋₈-Cys-Xaa₀₋₂, wherein Xaa=any amino acid (SEQ ID NO: 99) appended at the C-terminus.

C. Modification of Loop Region F385 Through K390

It has now been discovered that a loop region spanning amino acid residues F385 through K390 in SEQ ID NO: 18 (wild type E. coli BGUS) is important for effective hydrolysis of codeine glucuronide substrates. The preparation of mutant BGUS enzymes having this region deleted (referred to herein as K3Δ1, K3Δ2 and K3Δ2S) is described in detail in Example 2. The full-length amino acid sequences of the K3Δ1, K3Δ2 and K3Δ2S mutants are shown in SEQ ID NOs: 22, 23 and 24, respectively. The alignments of the K3Δ1, K3Δ2 and K3Δ2S mutant amino acid sequences as compared to wild-type (SEQ ID NO: 18) are shown in FIG. 1.

The enzymatic activity of the K3Δ1 mutant as compared to the K1S and K3 enzymes, as well as the commercially available snail (Helix pomatia) BGUS extract, against two different substrates is described in detail in Example 6 and Table 1. This data demonstrate that deletion of the F385 through K390 region does not significantly affect the enzymatic activity against phenolphthalein-glucuronide as a substrate but it does significantly affect the enzymatic activity against codeine-6-glucuronide as a substrate. In particular, deletion of this loop region reduces the activity of the E. coli BGUS for the codeine glucuronide substrate nearly as low as that of the snail BGUS, which lacks this loop region in its wild type form. Thus, this data indicates that this loop region is important for imparting to the BGUS enzyme the ability to efficiently hydrolyze codeine glucuronides.

Accordingly, in another aspect, the invention provides a BGUS mutant that comprises a modification of a region comprising amino acids corresponding to F385 through K390 in SEQ ID NO: 18. In one embodiment, the modification is a deletion of this region. For example, a BGUS enzyme that contains this region in its wild type form can be mutated to delete this region to thereby reduce the enzymatic activity of the enzyme against codeine glucuronide substrates. Alternatively, in another embodiment, the modification is an insertion of this region. For example, a BGUS enzyme that lacks this region in its wild type form can be mutated to insert this region to thereby impart or enhance enzymatic activity of the enzyme against codeine glucuronide substrates.

The term “modification of a region comprising amino acids corresponding to F385 through K390 in SEQ ID NO: 18”, as used herein, references the numbering of the wild type E. coli K12 strain BGUS enzyme as shown in SEQ ID NO: 18. That is, the wild type sequence shown in SEQ ID NO: 18 has the following residues: F385, E386, A387, G388, N389 and K390, and it is these amino acid residues, or amino acid residues corresponding to these residues in another BGUS sequence, that are to be modified.

As described above, the sequences of BGUS enzymes from numerous species are known in the art. To identify “a region comprising amino acids corresponding to F385 through K390 in SEQ ID NO: 18” in a BGUS enzyme sequence other than E. coli K12 strain, one of skill in the art can align the BGUS enzyme sequence to SEQ ID NO: 18 using standard computer programs for identifying protein homologies to determine the “best fit” alignment to thereby identify an amino acid residue in the non-E. coli K12 sequence that corresponds to F385 through K390 in SEQ ID NO: 18. For example, FIG. 2 shows a representative alignment of the E. coli K12 (K3 mutant), human, abalone, Lactobacillus brevis and Staphylococcus sp. RLH1 sequences across the region spanning F385 through K390 in SEQ ID NO: 18, with the amino acid position corresponding to this region in the five sequences indicated. Using such an approach, one of skill in the art can easily make a modification, such as an insertion into the human or abalone sequence that lacks this loop region, at the region corresponding to F385 through K390 in BGUS sequences other than E. coli K12. For example, FIG. 10A shows two representative insertions mutations (referred to as Ab1 and Ab2) of an amino acid sequence comprising the F385 through K390 sequence of SEQ ID NO: 18 into the wild type abalone sequence at the appropriate insertion region. Similarly, FIG. 10B shows two representative insertions mutations (referred to as Hu1 and Hu2) of an amino acid sequence comprising the F385 through K390 sequence of SEQ ID NO: 18 into the wild type human sequence at the appropriate insertion region.

Accordingly, in one embodiment of the invention, the mutated BGUS enzyme that comprises a modification of a region comprising amino acids corresponding to F385 through K390 in SEQ ID NO: 18 is from a bacteria, preferably E. coli, more preferably E. coli strain K12. In another embodiment, the mutated BGUS enzyme is from a mollusk, such as a snail (preferably Helix pomatia) or abalone (preferably Haliotus rufenscens). In still another embodiment, the mutated BGUS enzyme is from a mammal, preferably a human.

D. Combination Mutants

In another aspect, the invention pertains to mutant BGUS enzymes that contain two or more of the above described modifications, referred to herein as combination mutants.

Accordingly, in one embodiment, the invention provides a mutated β-glucuronidase enzyme comprising:

(i) a substitution of an amino acid corresponding to G559 in SEQ ID NO: 18 with an amino acid comprising a side chain comprising a non-aromatic hydroxyl group or histidine or asparagine; and

(ii) an addition of a cysteine residue appended at or near the carboxy terminus of the enzyme (e.g., wherein the carboxy terminus has the sequence: Xaa₂₋₈-Cys-Xaa₀₋₂, wherein Xaa=any amino acid).

In another embodiment, the invention provides a mutated β-glucuronidase enzyme comprising:

(i) a substitution of an amino acid corresponding to G559 in SEQ ID NO: 18 with an amino acid comprising a side chain comprising a non-aromatic hydroxyl group or histidine or asparagine; and

(ii) a modification of a region comprising amino acids corresponding to F385 through K390 in SEQ ID NO: 18.

In yet another embodiment, the invention provides a mutated β-glucuronidase enzyme comprising:

(i) a substitution of an amino acid corresponding to G559 in SEQ ID NO: 18 with an amino acid comprising a side chain comprising a non-aromatic hydroxyl group or histidine or asparagine;

(ii) an addition of a cysteine residue appended at or near the carboxy terminus of the enzyme (e.g., wherein the carboxy terminus has the sequence: Xaa₂₋₈-Cys-Xaa₀₋₂, wherein Xaa=any amino acid); and

(iii) a modification of a region comprising amino acids corresponding to F385 through K390 in SEQ ID NO: 18.

In still another embodiment, the invention provides a mutated β-glucuronidase enzyme comprising:

(i) an addition of a cysteine residue appended at or near the carboxy terminus of the enzyme (e.g., wherein the carboxy terminus has the sequence: Xaa₂₋₈-Cys-Xaa₀₋₂, wherein Xaa=any amino acid); and

(ii) a modification of a region comprising amino acids corresponding to F385 through K390 in SEQ ID NO: 18.

In these combination mutants having a G559 substitution, in one embodiment, the amino acid corresponding to G559 in SEQ ID NO: 18 is substituted with serine. In another embodiment, the amino acid corresponding to G559 in SEQ ID NO: 18 is substituted with threonine. In yet other embodiments, the amino acid corresponding to G559 in SEQ ID NO: 18 is substituted with a non-natural amino acid as described above in subsection IA.

In the combination mutants having a cysteine residue appended at the carboxy terminus, preferably a tripeptide Glycine-Leucine-Cysteine (GLC) or a pentapeptide Gly-Leu-Cys-Gly-Arg (GLCGR) is appended at the carboxy terminus.

A preferred combination mutant has a G559S substitution and a GLC tripeptide appended at the C-terminus. Preferably, this combination mutant has an amino acid sequence as shown in SEQ ID NO: 21. Another combination mutant has a G559H substitution and a GLC tripeptide appended at the C-terminus, such as the mutant having the amino acid sequence shown in SEQ ID NO: 62. Another combination mutant has a G559H substitution and a GLCGR pentapeptide appended at the C-terminus, such as the mutant having the amino acid sequence shown in SEQ ID NO: 63. Another combination mutant has a G559N substitution and a GLC tripeptide appended at the C-terminus, such as the mutant having the amino acid sequence shown in SEQ ID NO: 65. Another combination mutant has a G559N substitution and a GLCGR pentapeptide appended at the C-terminus, such as the mutant having the amino acid sequence shown in SEQ ID NO: 66.

In a preferred embodiment, a combination mutant that comprises a substitution at position 559 and that has a cysteine residue appended at or near the C-terminal end has the amino acid sequence shown in SEQ ID NO: 93, wherein position 559 is substituted with Ser (S), Thr (T), His (H) or Asn (N) and wherein the C-terminal end has the following sequence: Xaa₂₋₈-Cys-Xaa₀₋₂, wherein Xaa=any amino acid.

In the combination mutants having a modification of the region comprising amino acids corresponding to F385 through K390 in SEQ ID NO: 18, in one embodiment this modification is a deletion of the region. Examples of mutant BGUS enzymes having a deletion of this region include those having the amino acid sequence set forth in SEQ ID NOs: 22, 23 and 24. In another embodiment, the modification is an insertion of the region, for example into a BGUS sequence from a species that does not naturally contain this region.

In one embodiment, a combination mutant as described above is from a bacteria, preferably from Escherichia coli, more preferably from Escherichia coli K12 strain. In another embodiment, the combination mutant is from a mollusk, such as a snail (preferably Helix pomatia) or an abalone (preferably Haliotus rufenscens). In yet another embodiment, the combination mutant is from a human.

In yet another embodiment, a combination mutant is from Staphylococcus sp. RLH1 (StBGUS). The amino acid sequence of a representative StBGUS combination mutant, having a G563S substitution and having a cysteine appended at the C-terminus, is shown in SEQ ID NO: 101. In alternative embodiments, a combination StBGUS mutant can comprise a substitution of G563 with an amino acid comprising a non-aromatic hydroxyl group (e.g., serine or threonine) or histidine or asparagine, and further can comprise an addition of a cysteine residue appended at or near the carboxy terminus of the enzyme, wherein the carboxy terminus has the sequence: Xaa₀₋₈-Cys-Xaa₀₋₂, wherein Xaa=any amino acid (SEQ ID NO: 99).

II. Preparation of Mutant Enzymes

The BGUS enzymes of the invention can be prepared using standard recombinant DNA techniques. A preferred method for mutation is to perform overlap extension PCR using primers that incorporate the desired mutation(s), as described in detail in Example 2. Other methods known in the art for protein mutagenesis, however, are also suitable. Once a nucleic acid fragment encoding the desired mutant BGUS enzyme has been obtained, the fragment can be inserted into a suitable expression vector, transformed into a suitable host cell and the mutant protein expressed recombinantly by culturing of the host cell. Representative non-limiting examples of suitable expression vectors and host cells are described in Example 2, although the skilled artisan will appreciate that any of a variety of expression systems known in the art can be used.

Following recombinant expression of the mutant BGUS enzyme, the protein can be purified using standard protein purification techniques For example, standard affinity chromatography methods, such as immunoaffinity chromatography using an anti-BGUS antibody or metal ion affinity chromatography using nickel, cobalt or copper resin, can be used. As described in detail in Example 6 and FIG. 9, recombinant mutant enzyme of the invention exhibits a significantly higher degree of purity than commercially available extracts from abalone, snail or humans. Thus, the recombinant mutant enzymes of the invention advantageously lack contaminating proteins found in commercially available crude extract preparations, which contaminating proteins could interfere with enzyme activity or efficiency.

III. Packaged Formulations

In another aspect, the invention pertains to packaged formulations that comprise a mutant BGUS enzyme of the invention. These packaged formulations comprise a container comprising a preparation of the mutant BGUS enzyme. Non-limiting examples of suitable containers include, bottles, tubes, vials, ampules and the like. Preferably, the container is glass or plastic, although other suitable materials are known in the art. The preparation of the mutant BGUS enzyme can be in liquid or solid form. Thus, in one embodiment, the enzyme preparation is an aqueous solution. In another embodiment, the enzyme preparation is a lyophilized preparation. Lyophilized preparations can be packaged with instructions for reconstituting the enzyme into a liquid solution (e.g., an aqueous solution).

Preferably, the preparation of β-glucuronidase enzyme in the packaged formulation has an enzymatic activity of at least 5,000 Units/ml or 5,000 Units/mg, more preferably at least 10,000 Units/ml or 10,000 Units/mg, even more preferably at least 25,000 Units/ml or 25,000 Units/mg and even more preferably 50,000 Units/ml or 50,000 Units/mg. In one embodiment, the β-glucuronidase enzyme in the preparation is in an aqueous solution with an enzymatic activity of at least 5,000 Units/ml, or at least 10,000 Units/ml or at least 25,000 Units/ml or at least 50,000 Units/ml. In another embodiment, the β-glucuronidase enzyme in the preparation is in lyophilized form with an enzymatic activity of at least 5,000 Units/mg, or at least 10,000 Units/mg or at least 25,000 Units/mg or at least 50,000 Units/mg. In yet another embodiment, the β-glucuronidase enzyme in the preparation is in lyophilized form that when reconstituted as an aqueous solution has an enzymatic activity of at least 5,000 Units/ml, or at least 10,000 Units/ml or at least 25,000 Units/ml or at least 50,000 Units/ml.

The specific activity of the enzyme in the preparation, in Units/ml or Units/mg, can be determined using a standardized glucuronide linkage hydrolysis assay using phenolphthalein-glucuronide as the substrate. The standardization of the specific activity of BGUS has been well established in the art. Thus, 1 Unit of BGUS activity is defined as an amount of enzyme that liberates 1 μg of phenolphthalein from phenolphthalein-glucuronide in 1 hour. An exemplary standardized assay that can be used to determine the specific activity (in Units/ml or Units/mg) of an enzyme preparation (e.g., an aqueous solution or lyophilized preparation) is described in further detail in Example 3. The skilled artisan will appreciate that other protocols for the enzyme assay are also suitable (e.g., such as those described by Sigma Aldrich Chemical Co.). The calculation of Units/ml or Units/mg based on the results of the enzymatic assay also is described in detail in Example 3.

In a preferred embodiment, the preparation containing the mutant BGUS enzyme is substantially free of other non-BGUS proteins. As used herein, “substantially free” refers to less than 5%, preferably less than 3%, even more preferably less than 1% of contamination non-BGUS proteins. In another preferred embodiment, the preparation containing the mutant BGUS enzyme lacks detectable sulfatase activity. In yet another preferred embodiment, the preparation containing the mutant BGUS enzyme is stable at least one month, more preferably at least three months, and even more preferably at least six months at 2-8° C. As used herein, “stable” refers to the mutant BGUS enzyme in the preparation maintaining at least 90%, more preferably at least 95%, even more preferably at least 98% of its enzymatic activity over the indicated time at the indicated temperature.

IV. Methods of Use

The mutant BGUS enzymes of the invention exhibit enhanced ability to hydrolyze glucuronide linkages as compared to the wild type enzyme. Accordingly, the mutant enzymes can be used in methods for hydrolysis of gluruonide substrates. These methods are particularly useful for analyzing bodily samples for the presence of drugs through detection of the glucuronide detoxification products of the drugs. Thus, in another aspect the invention pertains to a method of hydrolyzing a substrate comprising a glucuronide linkage, the method comprising contacting the substrate with a mutant β-glucuronidase enzyme of the invention under conditions such that hydrolysis of the glucuronide linkage occurs. Any of the mutant enzymes of the invention, including those having a single modification and those having more than one modification (i.e., combination mutants) can be used in the method.

In one embodiment, the substrate is an opiate glucuronide. Non-limiting examples of suitable opiate glucuronide substrates include morphine-3β-D-glucuronide, morphine-6β-D-glucuronide, codeine-6β-D-glucuronide, hydromorphone-3β-D-glucuronide, oxymorphone-3β-D-glucuronide, and combinations thereof. In another embodiment, the substrate is a benzodiazepine glucuronide. Non-limiting examples of suitable benzodiazepine glucuronide substrates include the glucuronides of oxazepam, lorazepam, temazepam, and alpha-hydroxy-alprazolam. Other suitable substrates include the glucuronides of buprenorphine, norbuprenorphine, 11-nor-Δ9-tetrahydrocannabinol-9-carboxylic acid, testosterone, androsterone, tapentadol, cyclobenzaprine, amitripyline and combinations thereof.

The methods of the invention can be used on a variety of different bodily samples. Non-limiting examples of suitable bodily samples include blood, urine, tissue or meconium obtained from a subject. Such samples can be obtained, stored and prepared for analysis using standard methods well established in the art.

Following hydrolysis by the enzyme, the cleavage products in the sample can be analyzed by standard methodologies, such as high performance liquid chromatography (HPLC), gas chromatography (GC) and/or mass spectrometry (MS). Such approaches for analysis of bodily samples for the presence of drugs are well established in the art. For example, a completely automated workflow for the hydrolysis and analysis of urine samples by LC-MS/MS, which can be applied using the mutant enzymes of the invention for hydrolysis, is described in Cabrices, O. G. et al., GERSTEL AppNote AN/2014/4-7.

In addition to its use in drug testing, a mutated BGUS enzyme of the invention can be used in essentially any other methodology for which the wild type BGUS enzyme can be used. For example, U.S. Pat. No. 5,599,670 describes a gene fusion system in which DNA encoding a BGUS enzyme is fused to DNA encoding a gene of interest to create a reporter gene system that can be used for a wide variety of genetic engineering purposes. Accordingly, the mutated BGUS enzymes of the invention can be used in this gene fusion system to enhance the enzymatic activity of the BGUS portion of the fusion protein.

The present invention is further illustrated by the following examples, which should not be construed as further limiting. The contents of Sequence Listing, figures and all references, patents and published patent applications cited throughout this application are expressly incorporated herein by reference.

EXAMPLES Example 1 Cloning of E. coli β-Glucuronidase (BGUS) Gene

In this example, the wild type E. coli BGUS sequence was cloned by polymerase chain reaction (PCR) based on the published E. coli K12 BGUS sequence derived from the E. coli genome (NCBI Reference Sequence NC_000913.2), shown in SEQ ID NO: 1. The forward primer used for PCR had the following sequence: GAGAGACATATGTTACGTCCTGTAGAAACCCC (SEQ ID NO: 2). The reverse primer for PCR had the following sequence: GAGAGAAAGCTTTCATTGTTTGCCTCCCTGCT (SEQ ID NO: 3). The forward primer contains an NdeI restriction site and the reverse primer contains a HindIII restriction site.

To isolate a sample of E. coli DH5α strain genomic DNA, 5 ml of LB culture were grown overnight and 1 ml of cells was pelleted in a 1.5 ml tube. The cells were resuspended in 50 μl of water and were heated at 95° C. for 5 minutes to lyse the cells. The debris was pelleted and 10 μl of supernatant was used as a template in the PCR reaction.

For the PCR reaction, the primers were diluted to 10 μM and 5 μl of each primer was used in a 50 μl PCR reaction (final primer concentration was 1 μM). The 50 μl reaction mixture contained the following: 10× ThermoPol Buffer (5 μl), 10 mM dNTP (1 μl), BGUS forward primer (5 μl), BGUS reverse primer (5 μl), E. coli DNA (10 μl), NEB Taq enzyme (1 μl), water (23 μl). The PCR program used for DNA amplification was as follows: 95° C./5 minutes, 40 cycles of 95° C./30 seconds, 50° C./30 seconds, 72° C./2.5 minutes, followed by 72° C./5 minutes, 4° C./∞.

After amplification, the PCR product was digested with NdeI and HindIII for cloning into a bacterial expression vector. The reaction mixture contained the following: PCR product (16 μl), NdeI (20 U/μl) (1 μl), HindIII (20 U/μl) (1 μl), 10×NEB Reaction Buffer 2 (2 μl). The restriction enzyme digestion reaction was carried out at 37° C. for 60 minutes.

The bacterial vector was prepared by digestion with NdeI and HindIII in a reaction mixture that contained the following: Vector (0.1 μg/μl) (10 μl), NdeI (20 U/μl) (1 μl), HindIII (20 U/μl) (1 μl), 10×NEB Reaction Buffer 2 (2 μl), water (6 μl). The restriction enzyme digestion reaction was carried out at 37° C. for 60 minutes. Then 2 μl of 10× Shrimp Alkaline Phosphatase (SAP) buffer and 1 μl of SAP enzyme was added to the restriction enzyme digestion for the vector and incubated at 37° C. for 30 minutes. All fragments were isolated on a 1% low melting point (LMP) agarose gel in 1× Tris-Acetate-EDTA running buffer.

The agarose fragments containing the vector and the insert DNA were melted at 68° C. for 10 minutes. A ligation reaction was prepared that contained the following: Vector/NdeI/HindIII/SAP (3 μl), BGUS ORF/NdeI/HindIII (7 μl), 10×NEB T4 DNA Ligase Buffer (5 μl), T4 DNA Ligase (400 U/μl)(1 μl), water (34 μl). The ligation reaction mixture was incubated at room temperature overnight.

Following the overnight ligation reaction, the T4 DNA ligase was heat inactivated by heating the reaction at 68° C. for 10 minutes. For transformation into competent cells, an aliquot of competent DH5α cells was thawed on ice and 150 μl of the competent cells as added to the ligation reaction and mixed by gentle pipetting. The cells were then incubated on ice for 30 minutes, followed by heat shock at 42° C. for 3 minutes. The cells were then placed back on ice for 2 minutes and then transferred to 1 ml of LB medium in a 14 ml culture tube. The cell culture was incubated at 37° C. for 60 minutes at 250 rpm. Aliquots of the cells were added to LB-Kanamycin plates and grown overnight at 37° C. Colonies were picked for plasmid extraction and analysis by DNA sequencing using standard techniques to identify a plasmid that contained the cloned E. coli wild type BGUS gene.

Example 2 Mutagenesis of E. coli β-Glucuronidase (BGUS) Gene

Overlap extension PCR was used to create mutations in the E. coli K12 BGUS ORF using the plasmid encoding the wild type enzyme as the template. Four primers were used to create the K1S mutant (having a G559S single amino acid substitution), as follows:

BGUS Forward: (SEQ ID NO: 4) CTGCTGTCGGCTTTAACCTC G559S Forward: (SEQ ID NO: 5) GACCTCGCAAAGCATATTGCG G559S Reverse: (SEQ ID NO: 6) CGCAATATGCTTTGCGAGGTC Vector Reverse: (SEQ ID NO: 7) CTAGTTATTGCTCAGCGGT

Two parallel PCR reactions were set up that were designed to produce the 5′ and 3′ parts of the desired mutated DNA fragments. Reaction 1 contained the following: 10×Pfu Buffer (5 μl), 10 mM dNTP (1 μl), 10 μM BGUS forward primer (1 μl), 10 μM G559 reverse primer (1 μl), wild-type plasmid template (0.1 μg/μl) (1 μl), Pfu enzyme (1 μl), water (40 μl). Reaction 2 contained the following: 10×Pfu Buffer (5 μl), 10 mM dNTP (1 μl), 10 M G559S forward primer (1 μl), 10 μM Vector reverse primer (1 μl), wild type plasmid template (0.1 μg/μl) (1 μl), Pfu enzyme (1 μl), water (40 μl). The PCR program used for DNA amplification was as follows: 95° C./5 minutes, 40 cycles of 95° C./30 seconds, 50° C./30 seconds, 72° C./60 seconds, followed by 72° C./5 minutes, 4° C./∞.

The DNA fragments were purified using an Omega Cycle Pure Kit and the two purified fragments were mixed together to form the final (mutated) product in a PCR reaction that contained the following: 10×Pfu Buffer (5 μl), 10 mM dNTP (1 μl), 10 μM BGUS forward primer (1 μl), 10 μM Vector reverse primer (1 μl), Fragment 1 (10 μl), Fragment 2 (10 μl), Pfu enzyme (1 μl), water (31 μl). The PCR program used for DNA amplification was as follows: 95° C./5 minutes, 40 cycles of 95° C./30 seconds, 50° C./30 seconds, 72° C./90 seconds, followed by 72° C./5 minutes, 4° C./o.

The final DNA fragment was purified using an Omega Cycle Pure Kit. The fragment was digested with BstB1 and HindIII restriction enzymes in pUC19 bacterial vector. The recipient bacterial plasmid was digested with BstB1 and HindIII, followed by treatment with SAP. All fragments were isolated on an LMP gel and an in gel ligation reaction was performed using standard techniques. Plasmid DNA was isolated for sequencing to identify the mutant clone. For large-scale expression of the mutant enzyme, the coding sequence of the mutant enzyme was cloned into the bacterial expression vector pSF-TAC (commercially available from Sigma Aldrich) or pD441-NH (commercially available from DNA2.0), both of which vectors contain an IPTG-inducible TAC or T5 promoter and a kanamycin resistance gene.

The protocol used to produce additional mutants was very similar to that described above for preparing the K1S mutant, except that each mutant had a specific pair of mutagenic primers for use in the overlap extension PCR. To prepare the K1T, K3, K3Δ1, K3Δ2 and K3Δ2S mutants, the following primers were used in overlap extension PCR reactions as described above:

Mutant Forward Primer Reverse Primer K1T GCGACCTCGCAAACCATATTG GCGCAATATGGTTTGCGAGGT CGC CGC (SEQ ID NO: 8) SEQ ID NO: 9) K3 CAAACAAGGCCTATGCTAGAA CAAGCTTCTCCTTTCTAGCAT AGGAGAAGCTTG AGGCCTTGTTTG (SEQ ID NO: 10) (SEQ ID NO: 11) K3Δ1 TCTTTAGGCATTGGTCCGAAA GTACAGTTCTTTCGGACCAAT GAACTGTAC GCCTAAAGA (SEQ ID NO: 12) (SEQ ID NO: 13) K3Δ2 TCTTTAGGCATTGGTGAAGAG GTTGACTGCCTCTTCACCAAT GCAGTCAAC GCCTAAAGA (SEQ ID NO: 14) (SEQ ID NO: 15) K3Δ2S CCGCAGTTCTTCAACGGGGAA GAAGAACTGCGGACCAATGCC ACTCAG TAAAGAG (SEQ ID NO: 16) (SEQ ID NO: 17)

For the K1T mutant, the wild type BGUS sequence was used as the PCR template, similar to as described above for the K1S mutant. The resultant K1T mutant contains a G559T single amino acid substitution.

For the K3 mutant, the K1S mutant sequence was used as the PCR template. The K3 mutant contains a G559S single amino acid substitution and also contains a “GLC” tripeptide added onto the C-terminal end of the protein.

For the K3Δ1 mutant, the K3 mutant sequence was used as the PCR template. The K3Δ1 mutant contains a G559S single amino acid substitution, a “GLC” tripeptide added onto the C-terminal end of the protein and a deletion of amino acid residues F385 through K390.

For the K3Δ2 mutant, the K3 mutant sequence was used as the PCR template. The K3Δ2 mutant contains a G559S single amino acid substitution, a “GLC” tripeptide added onto the C-terminal end of the protein and a deletion of amino acid residues F385 through S396.

For the K3Δ2S mutants, the K3 mutant sequence was used as the PCR template. The K3Δ2S mutant contains a G559S single amino acid substitution, a “GLC” tripeptide added onto the C-terminal end of the protein, a deletion of amino acid residues F385 through S396 and the following additional substitutions: E397P, E398Q, A399F and V400F.

Following PCR amplification and plasmid ligation as described above, the plasmid DNA was isolated for sequencing to identify the mutant clones. An alignment of the amino acid sequences of the K1S, K1T, K3, K3Δ1, K3Δ2 and K3Δ2S mutants compared to the wild type sequence is shown in FIG. 1.

An alignment of the amino acid sequences of the E. coli K3 mutant, the abalone wild type BGUS, the human wild type BGUS, the Lactobacillus brevis wild type BGUS and the Staphylococcus sp. RLH1 wild type BGUS across amino acid residues 332-416 (E. coli numbering), including across the modification region F385 through S396 (E. coli numbering), is shown in FIG. 2. Identical amino acid residues across the five sequences are highlighted in grey. The conserved glutamic acid residue (E) at position 413 (E. coli numbering) within the catalytic site is highlighted in bold, indicating the accuracy of the alignment. This conserved residue within the catalytic domain is described further in J. Biol. Chem. (1996) vol. 273(51), pp. 34507-34602 and Proc. Natl. Acad. Sci. USA (1995) vol. 92(15), pp. 7090-7094. The modification region F385 through S396 (E. coli numbering) is highlighted in bold and underlined.

An alignment of the amino acid sequences of the E. coli K3 mutant, the abalone wild type BGUS, the human wild type BGUS, the Lactobacillus brevis wild type BGUS and the Staphylococcus sp. RLH1 wild type BGUS across amino acid residues 452-606 (E. coli numbering), including across the G559S modification (E. coli numbering) and the C-terminal GLC modification, is shown in FIG. 3. Identical amino acid residues across the five sequences are highlighted in grey. The conserved tyrosine residue (Y) at position 468 and glutamic acid residue (E) at position 504 (E. coli numbering) within the catalytic site is highlighted in bold, indicating the accuracy of the alignment. These conserved residues within the catalytic domain are described further in J. Biol. Chem. (1996) vol. 273(51), pp. 34507-34602 and Proc. Natl. Acad. Sci. USA (1995) vol. 92(15), pp. 7090-7094. The G559S (E. coli numbering) and C-terminal GLC modifications are highlighted in bold and underlined.

Example 3 β-Glucuronidase Enzymatic Activity Assay

In this example, a standard enzyme activity assay for BGUS is described. The standard reporting format for this assay is in Units/ml for liquid formulations or in Units/mg for lyophilized formulations.

An activity assay buffer, 20 mM potassium phosphate buffer, pH 6.8, was prepared. The substrate solution used was 1 mM phenolphthaleine-glucuronide (PT-gluc) in water, prepared fresh. 400 μl of activity buffer was pipetted into a clean 1.5 ml microfuge tube. 4 μl of enzyme solution was added to the buffer to achieve a 1:100 dilution of the enzyme. Then, 30 μl of the diluted enzyme solution was pipetted in each well of a 96-well plate, with each enzyme solution performed in triplicate. 30 μl of diluted control enzyme solution was pipetted into control wells in triplicate. 30 μl of the PT-gluc substrate solution was pipetted into the wells with the enzyme solution. The plates were incubated for 30 minutes at 25° C. 180 μl of glycine was added to stop the reaction and develop color in each well. The absorbance at 540 nm was measured by standard methods.

1 Unit of BGUS activity is defined as an amount of enzyme that liberates 1 μg of phenolphthalein from phenolphthalein-glucuronide in 1 hour. Thus, to determine Units/ml of enzyme, first a standard curve was prepared by plotting background-subtracted absorbance at 540 nm for the phenolphthalein (PT) standards. Assuming a linear plot for the standard curve, the formula for determining the concentration of PT liberated by the enzyme is as follows:

[conc. PT in μg]=[(corrected absorbance at 540 nm)−(y intercept value)]/slope

The specific activity of the enzyme was determined by correcting for time and dilution factors, divided by the volume of enzyme used. Thus, to calculate the specific activity in Units/ml using the assay protocol above, the following formula was used:

Units/mL=(μg of PT released)×2×100/0.03

Example 4 Enzymatic Activity of β-Glucuronidase Mutants

In this example, the enzymatic assay of the BGUS mutants was examined in a series of experiments comparing their activity to wild type E. coli BGUS, as well as to another mutant previously described in the art or to a commercially available Helix pomatia (snail) BGUS enzyme extract. Different glucuronide substrates were examined, as described further below, using the enzymatic activity assay described in Example 3

In a first experiment, the specific activity of the K1S mutant, as compared to the wild type E. coli enzyme, was tested using the enzymatic activity assay described in Example 3 that uses phenolphthalein-glucuronide as the substrate. The results are shown in FIG. 4. The results demonstrate that the K1S mutant exhibits significantly increased specific enzyme activity (over 3-fold greater activity) compared to the wild type enzyme.

In a second experiment, the specific activity of the K1S mutant was compared to the wild type E. coli BGUS enzyme and to a thermo-resistant mutant that was reported in Xiong, A-S. et al. (2007) Prot. Eng. Design Select. 20:319-325. The thermoresistant mutant described in Xiong et al. (referred to in FIG. 5 as “TR” and referred to in Xiong et al. as GUS-TR3337) contains the G559S substitution but also contains five other single residue substitutions: Q439R, T509A, M532T, N550S and N566S. The enzyme reaction used approximately 500 ng of purified enzyme incubated with 750 μM concentration of 4-nitrophenol glucuronide as the substrate, followed by measurement of absorbance at 405 nm. The results are shown in FIG. 5. The results demonstrate that the K1S mutant exhibits significantly increased specific enzyme activity (over 3-fold greater activity) compared to both the wild type enzyme and the previously-reported TR (GUS-TR3337) mutant.

In a third experiment, the specific activity of the K1T, K3, K3-C606S and K3Δ1 mutants, as compared to the K1S mutant, was tested. The results are shown in FIG. 6. The results demonstrate that the K1T and K3 mutants exhibit specific enzyme activity that is equal to or greater than that of the K1S mutant, whereas the K3-C606S and K3Δ1 mutants exhibit specific activity that is lower than that of the K1S mutant, although still higher than the wild type enzyme.

The K3-C606S mutant differs from the K3 mutant in that the C-terminal cysteine in K3 has been substituted with a serine. Thus, the results with K3-C606S as compared to K3 demonstrate the contribution of the C-terminal cysteine to the enzymatic activity. The K3Δ1 mutant differs from the K3 mutant in that residues F385 through K390 have been deleted. Thus, the results with K3Δ1 as compared to K3 demonstrate the contribution of the F385-K390 loop region to the enzymatic activity.

In a fourth experiment, the role of the F385-K390 loop region was further examined by comparing hydrolysis of two different substrates, phenolphthalein-glucuronide and codeine-6-glucuronide, by the K1S, K3 and K3Δ1 mutants as compared to commercially available wild type Helix pomatia BGUS enzyme. The specific activities of the enzymes (in kU/ml) was determined using the phenolphthalein-glucuronide hydrolysis assay described above. For the codeine-6-glucuronide hydrolysis, the reaction mixtures contained 200 μl of drug-free urine sample, 40 μl enzyme, 50 μl rapid hydrolysis buffer and 10 μl codeine-D₆ (10 ppm) in acetonitrile. The reactions were incubated at 55° C. for 60 minutes. The results are shown below in Table 1:

TABLE 1 Specific enzyme activity codeine (kU/ml) (ppb) No enzyme NA NF K1S 73 935.0 K3 83 881.8 K3Δ1 78 345.1 Helix pomatia without 114 NF incubation Helix pomatia with 30 min. 114 129.1 incubation NF = not found, NA = not applicable, ppb = parts per billion

The results showed that for the phenolphthalein-glucuronide substrate, the BGUS mutants and the commercially available snail extract had similar specific activities, with the snail extract exhibiting slightly higher activity than the E. coli BGUS mutants.

The hydrolysis of codeine-6-glucuronide, however, differed among the enzymes tested. Both the K1S and K3 mutants exhibited efficient hydrolysis of codeine-6-glucuronide, recovering 935.0 and 881.8 ppb codeine, respectively, from 1000 ppb of codeine-6-glucuronide substrate. In contrast, the K3Δ1 mutant, which differs from K3 in that K3Δ1 has a deletion of the loop region F385-K390, only recovered 345.1 ppb codeine from 1000 ppb codeine-6-glucuronide substrate. This result demonstrates that deletion of this loop region depresses the hydrolysis of the codeine glucuronides. In comparison, the Helix pomatia (snail) enzyme had a very low hydrolysis of codeine-6-glucuronide (129.1 ppb recovered from 1000 ppb substrate), despite having a higher specific activity than the E. coli mutants for the phenolphthalein-glucuronide substrate. This result is consistent with the F385-K390 loop region being important for hydrolysis of codeine glucuronides, since the Helix pomatia amino acid sequence lacks a region corresponding to the F385-K390 loop region of E. coli. Thus, based on these studies, one can mimic the level of snail BGUS activity for codeine glucuronides by replacing of this loop region in BGUS enzymes that contain the loop (e.g., E. coli). Moreover, one can improve the level of BGUS activity for codeine glucuronides by inserting this loop region into BGUS enzymes that lack the loop (e.g., snail, abalone or human versions of BGUS).

Example 5 Thermostability of β-Glucuronidase Mutants

To examine the heat stability of the mutants, the enzymes were either unheated, or heated for 30 or 60 minutes at 65° C., and the percent of original enzyme activity left after heating was measured. In a first series of experiments, the thermostability of the K1S, K3, K3-C606S and K1T enzymes were compared. The results demonstrate that the K3 mutant, which has a C-terminal cysteine residue modification, exhibits a higher thermostability that the K1S and K1T mutants, which lacks this C-terminal cysteine. The mutation of the cysteine residue at the carboxy terminus of the K3 mutant to serine, to form the K3-C606S variant, eliminates this heat stability, thereby demonstrating the contribution of the C-terminal cysteine to the thermostability. Wild type enzyme had similar heat stability as K1S.

The thermostability of the K3 mutant was further examined at four different temperatures using a 2 hour incubation period. Enzyme mixtures, containing buffer and analytes, were incubated at either 4° C., 20° C., 37° C. or 55° C. Enzyme activity was measured both pre- and post-incubation. The results are shown in FIG. 10, expressed as kU/mL, comparing the pre- and post-incubation enzymatic activity at the four different temperatures. The results demonstrate the stability of the purified, recombinant K3 mutant enzyme at the four different temperatures, showing no loss of enzyme activity over time at any of the temperatures tested.

A further analysis of the effect of C-terminal mutations on the thermostability of the BGUS enzyme is described in Example 8 below.

Example 6 Further Characterization of β-Glucuronidase K3 Mutant

In this example, the effects of pH on the activity of the BGUS K3 mutant, as well as the purity of the protein, were further characterized.

Effect of pH

The relative enzyme activity was measured at various pH levels to examine the effect of pH on the enzyme activity. The results are shown in FIGS. 7A and 7B for the K3 mutant. For the results shown in FIG. 7A, the enzyme activity dropped significantly when the buffer solution pH was below 6. The optimal pH range for enzyme activity was within pH 7-8. For the results shown in FIG. 7B, the enzyme was stored overnight at different pH levels and then enzyme activity was tested by bringing the pH back to neutral levels. Thus comparing the results in FIGS. 7A and 7B, the results showed that although the pH level affects the enzymatic activity, it does not affect the stability of the enzyme in the short term during storage when the pH is returned to neutral levels for testing enzyme activity.

Purity

The recombinant K3 enzyme was purified by standard affinity purification and the resultant purified protein was examined by SDS-PAGE as compared to commercially available preparations of BGUS protein from different species. The results are shown in FIG. 8, in which lane 1 shows the molecular weight markers, lane 2 shows the K3 mutant, lane 3 shows a commercially available abalone BGUS preparation, lane 4 shows a commercially available snail BGUS preparation and lane 5 shows a commercially available E. coli BGUS preparation. The results show that each of the commercially available BGUS preparations contained extraneous proteins that may interfere with downstream analytical processing of test samples, whereas the purified recombinant K3 preparation did not contain these extraneous proteins.

Example 7 Further Analysis of β-Glucuronidase Position 559 Mutants

In this example, the wild-type glycine at position 559 of BGUS was substituted with each of the 19 other natural amino acids to determine the effect of the substitutions on enzyme activity. Each 559 position mutant also included the “GLC” addition at the C-terminal end (as in the K3 enzyme) to enhance thermostability.

In addition to the G559S and G559T mutations described above, the 17 other point mutations at position 559 were prepared using the following forward primers in overlap extension PCR reactions as described above. All reactions used the following as the reverse primer: GCAAAATCGGCGAAATTC (SEQ ID NO: 43).

Mutant Forward Primer G559A GACCTCGCAAGCAATATTGCGCGTTG (SEQ ID NO: 44) G559C GACCTCGCAATGTATATTGCGCGTTG (SEQ ID NO: 45) G559D GACCTCGCAAGATATATTGCGCGTTG (SEQ ID NO: 46) G559E GACCTCGCAAGAAATATTGCGCGTTG (SEQ ID NO: 47) G559F GACCTCGCAATTCATATTGCGCGTTG (SEQ ID NO: 48) G559H GACCTCGCAACATATATTGCGCGTTG (SEQ ID NO: 49) G559I GACCTCGCAAATCATATTGCGCGTTG (SEQ ID NO: 50) G559K GACCTCGCAAAAAATATTGCGCGTTG (SEQ ID NO: 51) G559L GACCTCGCAACTGATATTGCGCGTTG (SEQ ID NO: 52) G559M GACCTCGCAAATGATATTGCGCGTTG (SEQ ID NO: 53) G559N GACCTCGCAAAACATATTGCGCGTTG (SEQ ID NO: 54) G559P GACCTCGCAACCGATATTGCGCGTTG (SEQ ID NO: 55) G559Q GACCTCGCAACAGATATTGCGCGTTG (SEQ ID NO: 56) G559R GACCTCGCAACGTATATTGCGCGTTG (SEQ ID NO: 57) G559V GACCTCGCAAGTGATATTGCGCGTTG (SEQ ID NO: 58) G559W GACCTCGCAATGGATATTGCGCGTTG (SEQ ID NO: 59) G559Y GACCTCGCAATACATATTGCGCGTTG (SEQ ID NO: 60) Enzyme activity was tested as described in the previous examples. The results for the 19 different position 559 point mutations, as compared to the wild type glycine (G), are shown in FIG. 11. The results demonstrate that substitution at position 559 with either serine (S), threonine (T), histidine (H) or asparagine (N) (as compared to the wild-type glycine (G)) resulted in enhanced enzyme activity.

Example 8 Further Analysis of β-Glucuronidase C-Terminal Mutants

In this example, the C-terminal end of the BGUS enzyme was mutated with various substitutions and/or insertions to determine the effect on overall enzyme activity and thermostability. The mutations made at the C-terminal end are shown below in Table 2. Each mutant also included the G559S mutation. The entire amino acid sequence of each mutant is shown in the Sequence Listing at the indicated SEQ ID NOs. Additionally, the forward and reverse primers used to prepare the mutants in overlap extension PCR reactions are shown in the Sequence Listing at the indicated SEQ ID NOs.

TABLE 2 Mutant Mutant Forward Reverse Portion of SEQ Primer Primer Mutation Type BGUS ID NO: SEQ SEQ Serine (S) SSCXX 67 79 85 Glutamic Acid EECXX 68 80 85 (E) Lysine (K) KKCXX 69 81 85 Alanine (A) AACXX 70 82 85 Tryptophan WWCXX 71 83 85 (W) Proline (P) PPCXX 72 84 85 1 GLGCXX 73 86 92 2 GLGGCXX 74 87 92 3 GLGGGCXX 75 88 92 4 GLGGGGCXX 76 89 92 5 GLGGGGGCXX 77 90 92 6 GLGGGGGGCXX 78 91 92 Enzyme activity was tested as described in the previous examples. Purified enzymes were heat treated for one hour prior to measuring their enzymatic activity. The results are shown in FIG. 12. All substitution and insertion mutations tested showed similar enzymatic activity as that of the positive control, thereby demonstrating that the mutations near the carboxy terminus do not affect the overall enzyme activity. Furthermore, the heat pre-treatment did not affect the enzymatic activity, thereby demonstrating that the substitutions and insertions around the cysteine residue did not affect the thermostability. Thus, these results indicate that the length and type of amino acid variation prior to the cysteine residue near the carboxy terminus is not critical for maintaining enzymatic activity and thermostability.

The thermostability of C-terminal mutations was further examined by incubating various mutants at 65° C. for 30 or 60 minutes. The results are shown below in Table 3:

TABLE 3 Percent Activity after Incubation at 65° C. Mutant 30 Minutes 60 Minutes K1T 0 0 K1S 0.53 ND K1S + G 0 ND K1S + GL 0.55 ND K1S + GLC (K3) 19.0 ND K1S + GLCG 22.0 ND K1S + GLCGR 27.6   6.0 K1S + GLSGR 0 0 ND = not determined First, the results in Table 3 confirm the previously reported results that adding the “GLC” tripeptide to the C-terminus (shown in the table as K1S+GLC (K3)) significantly increases the thermostability as compared to enzymes that lack this tripeptide (K1S or K1T) or that only include a “G” (K1S+G) or “GL” (K1S+GL) addition to the C-terminus. Furthermore, adding one residue (K1S+GLCG) or two residues (K1S+GLCGR) on the C-terminal side of the added cysteine residue maintains this enhanced thermostability. The mutant with two residues added beyond the cysteine residue (K1S+GLCGR) exhibited the greatest thermostability of all mutants tested. Finally, substitution of the cysteine with a serine (K1S+GLSGR) abolished the enhanced thermal stability, thereby demonstrating that the cysteine residue is critical for the enhanced thermal stability.

Example 9 Preparation and Analysis of Staphylococcus sp. RlH1 β-Glucuronidase Position 563 Mutant

In this example, the Staphylococcus sp. RLH1 BGUS (StBGUS) amino acid sequence was mutated at position 563 from glycine to serine (G563S) and the activity of the mutated enzyme was evaluated compared to the wild-type enzyme. Position 563 of the StBGUS enzyme corresponds to position 559 of the E. coli enzyme as described herein.

The BGUS wild type nucleotide sequence from Staphylococcus sp. RLH1 was synthesized by DNA 2.0 and cloned into a bacteria expression vector (pJ414). The StBGUS ORF (open reading frame) from pJ414 was cloned using PCR amplification with the following primers to transfer to a yeast expression vector (pD915).

StBGUS-Y-F-2: (SEQ ID NO: 102) 5′-GAGAGAGCTAGCATGTTATATCCGATCAATACTGAA-3′ StBGUS-Y-R-2: (SEQ ID NO: 103) 5′-GGACTAGTTCATTAGTTCTTGTAGCCAAAATC-3′ The PCR reaction to amplify the StBGUS ORF contained the following: StBGUS-pJ414 plasmid template (260 ng/μl) (0.5 μl), 10 μM forward primer (5 μl), 10 μM reverse primer (5 μl), 10×Pfx Buffer (5 μl), 10 mM dNTP (1.5 μl), 50 mM MgSO₄ (1 μl), Pfx DNA polymerase (1 μl), sterile double-distilled water (31 μl). The PCR program used for DNA amplification was as follows: 94° C./2 minutes, 30 cycles of 94° C./30 seconds, 55° C./30 seconds, 72° C./2 min, 30 seconds, followed by 72° C./10 minutes, 4° C./∞.

The PCR product was double digested with BmtI and SpeI restriction enzymes and ligated to pD915 vector. The ligated vector was further amplified using transformed DH5alpha cells with zeocin as the selection marker. The plasmid from the bacteria cells was isolated, linearized and used to transform yeast cells (Pichia pastoris) by electroporation. The transformed yeast cells were selected using YPD plates with zeocin and x-gluc. The blue colonies were selected and further cultured for screening.

Based on the Q5 Site-Directed Mutagenesis Kit, primers were designed for mutation of StBGUS 1687 nucleotide to mutate the glycine at amino acid position 563 to serine (G563S, referred to herein as the St1F mutant). The following forward and reverse primers were used for mutagenesis:

Q5-St1F-F (SEQ ID NO: 104) 5′-GACGAGCCAGAGCGTGATGCG-3′ Q5-St1F-R (SEQ ID NO: 105) 5′-GCGAAATCCGCGAAATTCC-3′

The PCR reaction to mutate the StBGUS wild type sequence contained the following: pD915-StBGUS plasmid template (10 ng/μl) (1 μl), 10 μM forward primer (1.25 μl), 10 μM reverse primer (1.25 μl), Q5 Hot Start Mix (12.5 μl), sterile double-distilled water (9 μl). The PCR program used for DNA amplification was as follows: 98° C./30 seconds, 25 cycles of 98° C./10 seconds, 65° C./30 seconds, 72° C./3 min, followed by 72° C./5 minutes, 4° C./.

The PCR product was treated with Kinase-Ligase-DpnI enzyme mixture (KLD) to form a circularized plasmid DNA, which was then used directly to transform competent cells for further amplification. The cloned cells were cultured overnight and the plasmid was isolated using a generic isolation kit. The plasmid was sequenced to confirm the mutation site using the following primers.

pD915-F-2 (SEQ ID NO: 106) 5′-TTTCTCCTGACCCAAAGACT-3′ PD915R (SEQ ID NO: 107) 5′-GCTGCGAGATAGGCTGAT-3′ The transformation and selection of St1F in yeast cells were performed as described above.

The secreted wild-type and mutant Staphylococcus sp. RLH1 beta glucuronidase (StBGUS and St1F) were isolated using several chromatography techniques established in the art (mixed mode cation exchange followed by hydrophobic interaction). The isolated enzyme was then dialyzed against 100 mM sucrose solution for further studies.

For enzyme activity assay, the following reagents were used in 96-well plate: enzyme sample (20 μl), 50 mM Kphos buffer, pH 6.8 (55 μl), 1 mM phenolphthalein β-D-glucuronide (25 μl). The reaction was incubated at 37° C. for 20 minutes, followed by addition of 150 μl of glycine buffer (0.2 M, pH 10.4). The absorbance was read at 540 nm and enzyme activity was calculated by using a phenolphthalein standard curve.

The results of the enzymatic activity analysis comparing wild-type StBGUS to the G563S mutant (St1F) are shown in FIG. 13. Enzyme activity was measured directly from culture media without purification (“culture supernatant” in FIG. 13), as well as using semi-purified protein (“purified protein” in FIG. 13). The normalized activity shown in FIG. 13 is activity divided by the protein band intensity. Protein band intensity was obtained by running 30 μl of sample on SDS-PAGE and then imaging the stained gel. The results in FIG. 13 demonstrate that, for both the unpurified and semi-purified samples, the G563S mutant (St1F) exhibited enhanced enzyme activity as compared to the wild-type StBGUS enzyme.

EQUIVALENTS

Those skilled in the art will recognize, or be able to ascertain using no more than routine experimentation, many equivalents of the specific embodiments of the invention described herein. Such equivalents are intended to be encompassed by the following claims.

SEQ ID NO: DESCRIPTION 1 E. coli K12 BGUS wild type nucleic acid sequence ATGTTACGTCCTGTAGAAACCCCAACCCGTGAAATCAAAAAACTCGACGGCCTGTGGGCA TTCAGTCTGGATCGCGAAAACTGTGGAATTGATCAGCGTTGGTGGGAAAGCGCGTTACAA GAAAGCCGGGCAATTGCTGTGCCAGGCAGTTTTAACGATCAGTTCGCCGATGCAGATATT CGTAATTATGCGGGCAACGTCTGGTATCAGCGCGAAGTCTTTATACCGAAAGGTTGGGCA GGCCAGCGTATCGTGCTGCGTTTCGATGCGGTCACTCATTACGGCAAAGTGTGGGTCAAT AATCAGGAAGTGATGGAGCATCAGGGCGGCTATACGCCATTTGAAGCCGATGTCACGCCG TATGTTATTGCCGGGAAAAGTGTACGTATCACCGTTTGTGTGAACAACGAACTGAACTGG CAGACTATCCCGCCGGGAATGGTGATTACCGACGAAAACGGCAAGAAAAAGCAGTCTTAC TTCCATGATTTCTTTAACTATGCCGGGATCCATCGCAGCGTAATGCTCTACACCACGCCG AACACCTGGGTGGACGATATCACCGTGGTGACGCATGTCGCGCAAGACTGTAACCACGCG TCTGTTGACTGGCAGGTGGTGGCCAATGGTGATGTCAGCGTTGAACTGCGTGATGCGGAT CAACAGGTGGTTGCAACTGGACAAGGCACTAGCGGGACTTTGCAAGTGGTGAATCCGCAC CTCTGGCAACCGGGTGAAGGTTATCTCTATGAACTGTGCGTCACAGCCAAAAGCCAGACA GAGTGTGATATCTACCCGCTTCGCGTCGGCATCCGGTCAGTGGCAGTGAAGGGCGAACAG TTCCTGATTAACCACAAACCGTTCTACTTTACTGGCTTTGGTCGTCATGAAGATGCGGAC TTGCGTGGCAAAGGATTCGATAACGTGCTGATGGTGCACGACCACGCATTAATGGACTGG ATTGGGGCCAACTCCTACCGTACCTCGCATTACCCTTACGCTGAAGAGATGCTCGACTGG GCAGATGAACATGGCATCGTGGTGATTGATGAAACTGCTGCTGTCGGCTTTAACCTCTCT TTAGGCATTGGTTTCGAAGCGGGCAACAAGCCGAAAGAACTGTACAGCGAAGAGGCAGTC AACGGGGAAACTCAGCAAGCGCACTTACAGGCGATTAAAGAGCTGATAGCGCGTGACAAA AACCACCCAAGCGTGGTGATGTGGAGTATTGCCAACGAACCGGATACCCGTCCGCAAGGT GCACGGGAATATTTCGCGCCACTGGCGGAAGCAACGCGTAAACTCGACCCGACGCGTCCG ATCACCTGCGTCAATGTAATGTTCTGCGACGCTCACACCGATACCATCAGCGATCTCTTT GATGTGCTGTGCCTGAACCGTTATTACGGATGGTATGTCCAAAGCGGCGATTTGGAAACG GCAGAGAAGGTACTGGAAAAAGAACTTCTGGCCTGGCAGGAGAAACTGCATCAGCCGATT ATCATCACCGAATACGGCGTGGATACGTTAGCCGGGCTGCACTCAATGTACACCGACATG TGGAGTGAAGAGTATCAGTGTGCATGGCTGGATATGTATCACCGCGTCTTTGATCGCGTC AGCGCCGTCGTCGGTGAACAGGTATGGAATTTCGCCGATTTTGCGACCTCGCAAGGCATA TTGCGCGTTGGCGGTAACAAGAAAGGGATCTTCACTCGCGACCGCAAACCGAAGTCGGCG GCTTTTCTGCTGCAAAAACGCTGGACTGGCATGAACTTCGGTGAAAAACCGCAGCAGGGA GGCAAACAATGA 2 GAGAGACATATGTTACGTCCTGTAGAAACCCC 3 GAGAGAAAGCTTTCATTGTTTGCCTCCCTGCT 4 CTGCTGTCGGCTTTAACCTC 5 GACCTCGCAAAGCATATTGCG 6 CGCAATATGCTTTGCGAGGTC 7 CTAGTTATTGCTCAGCGGT 8 GCGACCTCGCAAACCATATTGCGC 9 GCGCAATATGGTTTGCGAGGTCGC 10 CAAACAAGGCCTATGCTAGAAAGGAGAAGCTTG 11 CAAGCTTCTCCTTTCTAGCATAGGCCTTGTTTG 12 TCTTTAGGCATTGGTCCGAAAGAACTGTAC 13 GTACAGTTCTTTCGGACCAATGCCTAAAGA 14 TCTTTAGGCATTGGTGAAGAGGCAGTCAAC 15 GTTGACTGCCTCTTCACCAATGCCTAAAGA 16 CCGCAGTTCTTCAACGGGGAAACTCAG 17 GAAGAACTGCGGACCAATGCCTAAAGAG 18 Wild type E. coil K12 BGUS full length amino acid sequence (FIG. 1) 19 K1S mutant full length amino acid sequence (FIG. 1) 20 K1T mutant full length amino acid sequence (FIG. 1) 21 K3 mutant full length amino acid sequence (FIG. 1) 22 K3Δ1 mutant full length amino acid sequence (FIG. 1) 23 K3Δ2 mutant full length amino acid sequence (FIG. 1) 24 K3Δ2S mutant full length amino acid sequence (FIG. 1) 25 E. coil K3 mutant partial amino acid sequence, residues 332-416 (FIG. 2) 26 Abalone BGUS partial wild-type amino acid sequence (FIG. 2) 27 Human BGUS partial wild-type amino acid seqeuence (FIG. 2) 28 Lactobacillus brevis BGUS partial wild-type amino acid sequence (FIG. 2) 29 Staphylococcus sp. RLH1 partial wild-type amino acid sequence (FIG. 2) 30 E. coil K3 mutant partial amino acid sequence, residues 452-606 (FIG. 3) 31 Abalone BGUS partial wild-type amino acid sequence (FIG. 3) 32 Human BGUS partial wild-type amino acid seqeuence (FIG. 3) 33 Lactobacillus brevis BGUS partial wild-type amino acid sequence (FIG. 3) 34 Staphylococcus sp. RLH1 partial wild-type amino acid sequence (FIG. 3) 35 Abalone BGUS partial mutant amino acid sequence Ab1 (FIG. 9) 36 Abalone BGUS partial mutant amino acid sequence Ab 2 (FIG. 9) 37 Human BGUS partial mutant amino acid sequence Hu1 (FIG. 9) 38 Human BGUS partial mutant amino acid sequence Hu 2 (FIG. 9) 39 Human BGUS wild type amino acid sequence margsavawaalgpllwgcalglqggmlypqespsreckeldglwsfrad fsdnrrrgfeeqwyrrplwesgptvdmpvpssfndisqdwrlrhfvgwvwy erevilperwtqdlrtrvvlrigsahsyaivwvngvdtleheggylpfead isnlvqvgplpsrlritiainntltpttlppgtiqyltdtskypkgyfvqn tyfdffnyaglqrsvllyttpttyidditvttsveqdsglvnyqisvkgsn lfklevrlldaenkvvangtgtqgqlkvpgvslwwpylmherpaylyslev qltaqtslgpvsdfytlpvgirtvavtksqflingkpfyfhgvnkhedadi rgkgfdwpllvkdfnllrwlganafrtshypyaeevmqmcdrygivvidec pgvglalpqffnnvslhhhmqvmeevvrrdknhpavvmwsvanepashles agyylkmviahtksldpsrpvtfvsnsnyaadkgapyvdviclnsyyswyh dyghleliqlqlatqfenwykkyqkpiiqseygaetiagfhqdpplmftee yqkslleqyhlgldqkrrkyvvgeliwnfadfmteqsptrvlgnkkgiftr qrqpksaafllrerywkianetryphsvaksqclenslft 40 Mouse BGUS wild type amino acid sequence mslkwsacwvalgqllcscalalkggmlfpkespsrelkaldglwhfrad lsnnrlqgfeqqwyrqplresgpvldmpvpssfnditqeaalrdfigwvw yereailprrwtqdtdmrvvlrinsahyyavvwvngihvvehegghlpfe adisklvqsgplttcritiainntltphtlppgtivyktdtsmypkgyfv qdtsfdffnyaglhrsvvlyttpttyidditvitnveqdiglvtywisvq gsehfqlevqlldeggkvvahgtgnqgqlqvpsanlwwpylmhehpaymy slevkvtttesvtdyytlpigirtvavtkskflingkpfyfqgvnkheds dirgkgfdwpllvkdfnllrwlgansfrtshypyseevlqlcdrygivvi decpgvgivlpqsfgneslrhhlevmeelvrrdknhpavvmwsvanepss alkpaayyfktlithtkaldltrpvtfvsnakydadlgapyvdvicvnsy fswyhdyghleviqpqlnsqfenwykthqkpiiqseygadaipgihedpp rmfseeyqkavlenyhsvldqkrkeyvvgeliwnfadfmtnqsplrvign kkgiftrqrqpktsafilrerywrianetgghgsgprtqcfgsrpftf 41 Lactobacillus brevis BGUS wild type amino acid sequence mlypmetasrvvldlsgvwrfmidkeqipvdvtrplpatlsmavpasfnd qtaskeirehvgyvwyercfelpqllrqerlvlrfgsatheawvylnghl ithhkggftpfeveinddlvtgenrltvklsnmldyttlpvghyketqne tgqrvrqldenfdffnyaglqrpvkiystphsyirditltpkvnltnhsa vvngeietvgdveqvvvtildednqvvgttsgktlaielnsvhlwqpgka ylyrakvelyqagqvidtyietfgirqiavkagkflingqpfyfkgfgkh edayihgrglsepqnvldlslmkqmgansfrtshypyseemmrlcdregi vvidevpavglmlsftfdvsalekddfeddtweklrtaeahrqaitemid rdknhasvvmwsisneaanfskgayeyfkplfdlarkldpqqrpctstsi mmttlktdrclaladvialnryygwymgngdlkaaetatreellayqakf pdkpimyteygadtiaglhsnydepfseefqedyyrmcsrvfdevtnfvg eqlwnfadfqtkfgiqrgqgnkkgiftrarepkmvvryltqrwrnipdfn ykk 42 Staphylococcus sp. RLH1 BGUS wild type amino acid sequence mlypintetrgvfdlngvwnfkldygkgleekwyeskltdtismavpssy ndigvtkeirnhigyvwyereftvpaylkdqrivlrfgsathkaivyvng elvvehkggflpfeaeinnslrdgmnrvtvavdnilddstlpvglyserh eeglgkvirnkpnfdffnyaglhrpvkiyttpftyvedisvvtdfngptg tvtytvdfqgkaetvkvsvvdeegkvvasteglsgnveipnvilweplnt ylyqikvelvndgltidvyeepfgvrtvevndgkflinnkpfyfkgfgkh edtpingrgfneasnvmdfnilkwigansfrtahypyseelmrladregl vvidetpavgvhlnfmattglgegservstwekirtfehhqdvlrelvsr dknhpsvvmwsianeaateeegayeyfkplveltkeldpqkrpvtivlfv matpetdkvaelidvialnryngwyfdggdleaakvhlrqefhawnkrcp gkpimiteygadtvagfhdidpvmfteeyqveyyqanhvvfdefenfvge qawnfadfatsqgvmrvqgnkkgvftrdrkpklaahvfrerwtnipdfgy kn 43 GCAAAATCGGCGAAATTC 44 GACCTCGCAAGCAATATTGCGCGTTG 45 GACCTCGCAATGTATATTGCGCGTTG 46 GACCTCGCAAGATATATTGCGCGTTG 47 GACCTCGCAAGAAATATTGCGCGTTG 48 GACCTCGCAATTCATATTGCGCGTTG 49 GACCTCGCAACATATATTGCGCGTTG 50 GACCTCGCAAATCATATTGCGCGTTG 51 GACCTCGCAAAAAATATTGCGCGTTG 52 GACCTCGCAACTGATATTGCGCGTTG 53 GACCTCGCAAATGATATTGCGCGTTG 54 GACCTCGCAAAACATATTGCGCGTTG 55 GACCTCGCAACCGATATTGCGCGTTG 56 GACCTCGCAACAGATATTGCGCGTTG 57 GACCTCGCAACGTATATTGCGCGTTG 58 GACCTCGCAAGTGATATTGCGCGTTG 59 GACCTCGCAATGGATATTGCGCGTTG 60 GACCTCGCAATACATATTGCGCGTTG 61 E. coli K12 BGUS G559H mutant amino acid sequence mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq h ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq 62 E. coli K12 BGUS G559H + GLC C-terminal mutant amino acid sequence mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq h ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glc 63 E. coli K12 BGUS G559H + GLCGR C-terminal mutant amino acid sequence mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq h ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glcgr 64 E. coli K12 BGUS G559N mutant amino acid sequence mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq n ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq 65 E. coli K12 BGUS G559N + GLC C-terminal mutant amino acid sequence mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq n ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glc 66 E. coli K12 BGUS G559N + GLCGR C-terminal mutant amino acid sequence mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq n ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glcgr 67 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq sscxx 68 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwygrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq eecxx 69 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrysavvgegvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq kkcxx 70 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrysavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq aacxx 71 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlgaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnymfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrysavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq wwcxx 72 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnywygrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkgsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdysvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnymfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq ppcxx 73 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwygrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glgcxx 74 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glggcxx 75 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glgggcxx 76 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glggggcxx 77 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glgggggcxx 78 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glggggggcxx 79 AGCAGCTGCGGCCGGTAGAAAGGAG 80 GAAGAATGCGGCCGGTAGAAAGGAG 81 AAAAAATGCGGCCGGTAGAAAGGAG 82 GCGGCGTGCGGCCGGTAGAAAGGAG 83 TGGTGGTGCGGCCGGTAGAAAGGAG 84 CCGCCGTGCGGCCGGTAGAAAGGAG 85 TTGTTTGCCTCCCTGCTG 86 GGCTGCGGCCGGTAGAAAGGAG 87 GGCGGCTGCGGCCGGTAGAAAGGAG 88 GGCGGCGGCTGCGGCCGGTAGAAAGGAG 89 GGCGGCGGCGGCTGCGGCCGGTAGAAAGGAG 90 GGCGGCGGCGGCGGCTGCGGCCGGTAGAAAGGAG 91 GGCGGCGGCGGCGGCGGCTGCGGCCGGTAGAAAGGAG 92 TAGGCCTTGTTTGCCTCCC 93 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq z ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq x ₂₋₈ CX ₀₋₂, wherein z = s, t, h or n, and x = any a.a. 94 mlrpvetptreikkldglwafsldrencgidqrwwesalqesraiavpgs fndqfadadirnyagnvwyqrevfipkgwagqrivlrfdavthygkvwvn nqevmehqggytpfeadvtpyviagksvritvcvnnelnwqtippgmvit dengkkkqsyfhdffnyagihrsvmlyttpntwvdditvvthvaqdcnha svdwqvvangdvsvelrdadqqvvatgqgtsgtlqvvnphlwqpgegyly elcvtaksqtecdiyplrvgirsvavkgeqflinhkpfyftgfgrhedad lrgkgfdnvlmvhdhalmdwigansyrtshypyaeemldwadehgivvid etaavgfnlslgigfeagnkpkelyseeavngetqqahlqaikeliardk nhpsvvmwsianepdtrpqgareyfaplaeatrkldptrpitcvnvmfcd ahtdtisdlfdvlclnryygwyvqsgdletaekvlekellawqeklhqpi iiteygvdtlaglhsmytdmwseeyqcawldmyhrvfdrvsavvgeqvwn fadfatsq s ilrvggnkkgiftrdrkpksaafllqkrwtgmnfgekpqqg gkq glcgr 95 Xaa₂₋₈-Cys-Xaa₀₋₂, wherein Xaa = any amino acid 96 glcgr 97 Staphylococcus sp. RLH1 BGUS St1F (G563S) mutant nucleotide sequence atgttatatccgatcaatactgaaacgcgtggcgtctttgacttg aatggcgtctggaacttcaaactggactacggcaagggtctggaa gagaaatggtatgagagcaagctgacggacacgattagcatggca gtgccgagctcttacaacgatatcggtgttacgaaagaaatccgt aatcatattggttacgtctggtatgaacgtgagttcaccgtgccg gcgtacctgaaagaccagcgcatcgtgctgcgcttcggtagcgca acgcataaagccatcgtctatgtcaacggtgaactggttgtggag cacaagggtggctttctgccgtttgaggcagagattaataatagc ctgcgtgacggtatgaatcgcgtcacggttgcggtcgacaacatt ctggacgatagcaccttgccggtgggtctgtactccgagcgtcac gaagagggtctgggtaaggtcattcgtaacaaaccgaatttcgat ttcttcaattatgcgggcttgcaccgtccagtcaagatctacacg acgcctttcacctatgtggaagatattagcgttgtcaccgatttc aacggcccaaccggtaccgtgacctataccgtggattttcaaggt aaggccgagactgttaaagttagcgtcgttgacgaagaaggcaaa gttgtggcgagcaccgagggcctgtccggtaacgttgagattccg aatgttatcctgtgggagccgctgaacacctacctgtaccagatc aaagttgaactggttaatgatggtctgaccattgacgtgtacgaa gaaccgttcggtgtgcgtacggtcgaagtgaatgatggcaagttt ctgatcaacaacaaaccgttctactttaagggctttggcaaacac gaggataccccgatcaacggtcgtggttttaacgaagcgagcaat gtgatggacttcaacattctgaagtggattggcgcgaatagcttc cgtactgcccactatccgtactctgaggaacttatgcgtctggca gatcgcgagggcctggttgttatcgatgaaaccccggctgtcggt gttcacctgaactttatggccactacgggtctgggtgagggtagc gagcgcgtaagcacctgggagaaaattcgcacctttgagcatcac caggacgtgttgcgtgagctggtgagccgtgataagaatcacccg agcgttgtgatgtggagcatcgctaacgaagctgcaaccgaagaa gagggtgcgtatgagtactttaagccgctggttgagctgaccaaa gaattggacccgcagaagcgtcctgtgaccattgtcttgtttgtc atggccacgccggaaacggacaaagtcgcagagctgattgatgtt attgcgctcaaccgttacaatggttggtactttgacggtggcgac ctggaagcggcaaaagtgcatctgcgtcaagaattccacgcttgg aataagcgctgcccgggtaaaccgattatgatcaccgagtatggc gccgacaccgtggcgggtttccacgatatcgacccggttatgttt accgaagagtatcaagttgagtattaccaagcgaaccacgttgtt ttcgacgaattcgagaactttgtcggtgagcaagcctggaatttc gcggatttcgcgacgagccag

gtgatgcgtgtgcagggtaat aagaaaggcgtgttcacccgtgatcgtaagccgaaactggcggca cacgtgtttcgcgagcgttggaccaacatcccagattttggctac aagaactaa 98 Staphylococcus sp. RLH1 BGUS St1F (G563S) mutant amino acid sequence MLYPINTETRGVFDLNGVWNFKLDYGKGLEEKWYESKLTDTISMAVPSSY NDIGVTKEIRNHIGYVWYEREFTVPAYLKDQRIVLRFGSATHKAIVYVNG ELVVEHKGGFLPFEAEINNSLRDGMNRVTVAVDNILDDSTLPVGLYSERH EEGLGKVIRNKPNFDFFNYAGLHRPVKIYTTPFTYVEDISVVTDFNGPTG TVTYTVDFQGKAETVKVSVVDEEGKVVASTEGLSGNVEIPNVILWEPLNT YLYQIKVELVNDGLTIDVYEEPFGVRTVEVNDGKFLINNKPFYFKGFGKH EDTPINGRGFNEASNVMDFNILKWIGANSFRTAHYPYSEELMRLADREGL VVIDETPAVGVHLNFMATTGLGEGSERVSTWEKIRTFEHHQDVLRELVSR DKNHPSVVMWSIANEAATEEEGAYEYFKPLVELTKELDPQKRPVTIVLFV MATPETDKVAELIDVIALNRYNGWYFDGGDLEAAKVHLRQEFHAWNKRCP GKPIMITEYGADTVAGFHDIDPVMFTEEYQVEYYQANHVVFDEFENFVGE QAWNFADFATSQ S VMRVQGNKKGVFTRDRKPKLAAHVFRERWTNIPDFGY KN 99 Xaa₀₋₈-Cys-Xaa₀₋₂, wherein Xaa = any amino acid 100 Staphylococcus sp. RLH1 BGUS C-terminal Cvs mutant amino acid sequence MLYPINTETRGVFDLNGVWNFKLDYGKGLEEKWYESKLTDTISMAVPSSY NDIGVTKEIRNHIGYVWYEREFTVPAYLKDQRIVLRFGSATHKAIVYVNG ELVVEHKGGFLPFEAEINNSLRDGMNRVTVAVDNILDDSTLPVGLYSERH EEGLGKVIRNKPNFDFFNYAGLHRPVKIYTTPFTYVEDISVVTDFNGPTG TVTYTVDFQGKAETVKVSVVDEEGKVVASTEGLSGNVEIPNVILWEPLNT YLYQIKVELVNDGLTIDVYEEPFGVRTVEVNDGKFLINNKPFYFKGFGKH EDTPINGRGFNEASNVMDFNILKWIGANSFRTAHYPYSEELMRLADREGL VVIDETPAVGVHLNFMATTGLGEGSERVSTWEKIRTFEHHQDVLRELVSR DKNHPSVVMWSIANEAATEEEGAYEYFKPLVELTKELDPQKRPVTIVLFV MATPETDKVAELIDVIALNRYNGWYFDGGDLEAAKVHLRQEFHAWNKRCP GKPIMITEYGADTVAGFHDIDPVMFTEEYQVEYYQANHVVFDEFENFVGE QAWNFADFATSQGVMRVQGNKKGVFTRDRKPKLAAHVFRERWTNIPDFGY KN C 101 Staphylococcus sp. RLH1 BGUS StF1 + Cys mutant amino acid sequence MLYPINTETRGVFDLNGVWNFKLDYGKGLEEKWYESKLTDTISMAVPSSY NDIGVTKEIRNHIGYVWYEREFTVPAYLKDQRIVLRFGSATHKAIVYVNG ELVVEHKGGFLPFEAEINNSLRDGMNRVTVAVDNILDDSTLPVGLYSERH EEGLGKVIRNKPNFDFFNYAGLHRPVKIYTTPFTYVEDISVVTDFNGPTG TVTYTVDFQGKAETVKVSVVDEEGKVVASTEGLSGNVEIPNVILWEPLNT YLYQIKVELVNDGLTIDVYEEPFGVRTVEVNDGKFLINNKPFYFKGFGKH EDTPINGRGFNEASNVMDFNILKWIGANSFRTAHYPYSEELMRLADREGL VVIDETPAVGVHLNFMATTGLGEGSERVSTWEKIRTFEHHQDVLRELVSR DKNHPSVVMWSIANEAATEEEGAYEYFKPLVELTKELDPQKRPVTIVLFV MATPETDKVAELIDVIALNRYNGWYFDGGDLEAAKVHLRQEFHAWNKRCP GKPIMITEYGADTVAGFHDIDPVMFTEEYQVEYYQANHVVFDEFENFVGE QAWNFADFATSQ S VMRVQGNKKGVFTRDRKPKLAAHVFRERWTNIPDFGY KN C 102 GAGAGAGCTAGCATGTTATATCCGATCAATACTGAA 103 GGACTAGTTCATTAGTTCTTGTAGCCAAAATC 104 GACGAGCCAGAGCGTGATGCG 105 GCGAAATCCGCGAAATTCC 106 TTTCTCCTGACCCAAAGACT 107 GCTGCGAGATAGGCTGAT 

1. A mutated Staphylococcus sp. RLH1 β-glucuronidase (StBGUS) enzyme comprising a substitution of an amino acid corresponding to G563 in SEQ ID NO: 42 with an amino acid comprising a side chain comprising a non-aromatic hydroxyl group or histidine or asparagine.
 2. The mutated StBGUS enzyme of claim 1, wherein the amino acid corresponding to G563 in SEQ ID NO: 42 is substituted with a serine or threonine.
 3. The mutated StBGUS enzyme of claim 1, wherein the amino acid corresponding to G563 in SEQ ID NO: 42 is substituted with a serine.
 4. The mutated StBGUS enzyme of claim 1, which has the amino acid sequence shown in SEQ ID NO:
 98. 5. The mutated StBGUS enzyme of claim 4, which is encoded by the nucleotide sequence shown in SEQ ID NO:
 97. 6. A mutated Staphylococcus sp. RLH1 β-glucuronidase (StBGUS) enzyme comprising an addition of a cysteine residue appended at or near the carboxy terminus of the enzyme, wherein the carboxy terminus has the sequence: Xaa_(0.8)-Cys-Xaa₀₋₂, wherein Xaa=any amino acid (SEQ ID NO: 99).
 7. The mutated StBGUS enzyme of claim 6, which has the amino acid sequence shown in SEQ ID NO:
 100. 8. A mutated Staphylococcus sp. RLH1 β-glucuronidase (StBGUS) enzyme comprising: (i) a substitution of an amino acid corresponding to G563 in SEQ ID NO: 42 with an amino acid comprising a side chain comprising a non-aromatic hydroxyl group or histidine or asparagine; and (ii) an addition of a cysteine residue appended at or near the carboxy terminus of the enzyme, wherein the carboxy terminus has the sequence: Xaa_(0.8)-Cys-Xaa₀₋₂, wherein Xaa=any amino acid (SEQ ID NO: 99).
 9. The mutated StBGUS enzyme of claim 8, wherein the amino acid corresponding to G563 in SEQ ID NO: 42 is substituted with a serine or threonine.
 10. The mutated StBGUS enzyme of claim 8, wherein the amino acid corresponding to G563 in SEQ ID NO: 42 is substituted with a serine.
 11. The mutated StBGUS enzyme of claim 8, which has the amino acid sequence shown in SEQ ID NO:
 101. 12. A packaged formulation comprising a container comprising a preparation of the mutated StBGUS enzyme of claim 1, which has an enzymatic activity of at least 5,000 Units/ml or 5,000 Units/mg.
 13. The packaged formulation of claim 12, which is an aqueous solution with an enzymatic activity of at least 50,000 Units/ml.
 14. The packaged formulation of claim 12, which is a lyophilized preparation with an enzymatic activity of at least 50,000 Units/mg.
 15. The packaged formulation of claim 12, wherein the preparation is stable at least six months at 2-8° C.
 16. The packaged formulation of claim 12, wherein the preparation lacks detectable sulfatase activity.
 17. A method of hydrolyzing a substrate comprising a glucuronide linkage, the method comprising contacting the substrate with the mutated StBGUS enzyme of claim 1, under conditions such that hydrolysis of the glucuronide linkage occurs.
 18. The method of claim 17, wherein the substrate is an opiate glucuronide.
 19. The method of claim 18, wherein the opiate glucuronide is selected from the group consisting of morphine-3β-D-glucuronide, morphine-6β-D-glucuronide, codeine-6β-D-glucuronide, hydromorphone-3β-D-glucuronide, oxymorphone-3β-D-glucuronide, and combinations thereof.
 20. The method of claim 17, wherein the substrate is a benzodiazepine glucuronide.
 21. The method of claim 20, wherein the benzodiazepine glucuronide is selected from the group consisting of oxazepam-glucuronide, lorazepam-glucuronide, temazepam-glucuronide, alprazolam, alpha-hydroxy-alprazolam glucuronide, nordiazepam, 7-amino-clonozepam, and combinations thereof.
 22. The method of claim 17, wherein the substrate is in a sample of blood, urine, tissue or meconium obtained from a subject. 